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University of Kentucky University of Kentucky
UKnowledge UKnowledge
Theses and Dissertations--Chemical and Materials Engineering Chemical and Materials Engineering
2012
UNDERSTANDING DEGRADATION AND LITHIUM DIFFUSION IN UNDERSTANDING DEGRADATION AND LITHIUM DIFFUSION IN
LITHIUM ION BATTERY ELECTRODES LITHIUM ION BATTERY ELECTRODES
Juchuan Li University of Kentucky, [email protected]
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I retain all other ownership rights to the copyright of my work. I also retain the right to use in
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REVIEW, APPROVAL AND ACCEPTANCE REVIEW, APPROVAL AND ACCEPTANCE
The document mentioned above has been reviewed and accepted by the student’s advisor, on
behalf of the advisory committee, and by the Director of Graduate Studies (DGS), on behalf of
the program; we verify that this is the final, approved version of the student’s dissertation
including all changes required by the advisory committee. The undersigned agree to abide by
the statements above.
Juchuan Li, Student
Dr. Yang-Tse Cheng, Major Professor
Dr. Fuqian Yang, Director of Graduate Studies
UNDERSTANDING DEGRADATION AND LITHIUM DIFFUSION IN LITHIUM
ION BATTERY ELECTRODES
DISSERTATION
A dissertation submitted in partial fulfillment of the
requirements for the degree of Doctor of Philosophy in the
College of Engineering
at the University of Kentucky
By
Juchuan Li
Lexington, Kentucky
Director: Dr. Yang-Tse Cheng, Professor of Materials Engineering,
University of Kentucky, Lexington, Kentucky
Co-Director: Dr. Fuqian Yang, Professor of Materials Engineering
University of Kentucky, Lexington, Kentucky
2012
Copyright © Juchuan Li 2012
ABSTRACT OF DISSERTATION
UNDERSTANDING DEGRADATION AND LITHIUM DIFFUSION IN LITHIUM
ION BATTERY ELECTRODES
Lithium-ion batteries with higher capacity and longer cycle life than that available
today are required as secondary energy sources for a wide range of emerging applications.
In particular, the cycling performance of several candidate materials for lithium-ion
battery electrodes is insufficient because of the fast capacity fading and short cycle life,
which is mainly a result of mechanical degradation.
This dissertation mainly focuses on the issue of mechanical degradation in
advanced lithium-ion battery electrodes. Thin films of tin electrodes were studied where
we observed whisker growth as a result of electrochemical cycling. These whiskers bring
safety concerns because they may penetrate through the separator, and cause short-circuit
of the electrochemical cells. Cracking patterns generated in amorphous silicon thin film
electrodes because of electrochemical cycling were observed and analyzed. A two-
dimensional spring-block model was proposed to successfully simulate the observed
cracking patterns. With semi-quantitative study of the cracking pattern features, two
strategies to void cracking in thin-film electrodes were proposed, namely reducing the
film thickness and patterning the thin-film electrodes.
We also investigated electrodes consisting of low melting point elements and
showed that cracks can be self-healed by the solid-to-liquid phase transformation upon
cycling. Using gallium as an example, mechanical degradation as a failure mechanism for
lithium-ion battery electrodes can be eliminated.
In order to quantitatively understand the effect of surface modification on
electrodes, we analyzed diffusion equations with boundary conditions of finite interfacial
reactions, and proposed a modified potentialstatic intermittent titration technique (PITT)
as an electro-analytical technique to study diffusion and interfacial kinetics. The modified
PITT has been extended to thin-film geometry and spherical geometry, and thus can be
used to study thin-film and composite electrodes consisting of particles as active
materials.
KEY WORDS: lithium-ion batteries, mechanical degradation, crack, interfacial kinetics,
diffusion
Juchuan Li
03/28/2012
UNDERSTANDING DEGRADATION AND LITHIUM DIFFUSION IN LITHIUM
ION BATTERY ELECTRODES
By
Juchuan Li
Dr. Yang-Tse Cheng
Director of Dissertation
Dr. Fuqian Yang
Co-Director of Dissertation
Dr. Fuqian Yang
Director of Graduate Study
Date
Dedicated to my parents
iii
ACKNOWLEDGEMENTS
First, I want to express my deepest acknowledge to my co-advisors, Drs. Yang-
Tse Cheng and Fuqian Yang, for their continuous encourage and help during my doctoral
research. I enjoyed working with them on multidisciplinary research. Without them, this
dissertation would be impossible to finish.
I am also grateful to my committee members, Drs. T. John Balk, Christine Trinkle,
Adam Timmons (Chrysler), Steve Lipka (CAER), and Tate Tsang for their time, efforts,
and suggestions on my research and dissertation.
I would like to thank my lab mates, especially Rutooj D. Deshpande, Ilona
Hoffmann, Yunchao Li, Qinglin Zhang, Jie Pan, Jiagang Xu, Rong Chen, and Guangfeng
Zhao, for their support and help on my research. We have made our Ph.D. lives fun and
productive.
Researchers at GM R&D are greatly appreciated, including Drs. Mark W.
Verbrugge, Xingcheng Xiao, Steve Harris, Yan Wu, and Meng Jiang for their guidance
and support given to me. I am also grateful to GM for giving me summer internships and
visiting scientist status.
I would also like to thank people who helped my research: Dr. Qingliu Wu, Dr.
Alan K. Dozier, Lei Wang, Brian Wajdyk (CeNSE), Nancy Miller, and Dr. Jia Ye
(Microscopy Center). Co-authors of my publications at Department of Chemistry are
gratefully thanked: Aman Kaur, Dr. mark Meier, Rituraj Borgohain, and Dr. John
Selegue.
Thanks to the funding agencies which supported this dissertation: NSF, GM R&D,
and UK.
Finally, I would like to thank my parents for their unselfish support.
iv
TABLE OF CONTENTS
ACKNOWLEDGEMENTS ............................................................................................... iii
TABLE OF CONTENTS ................................................................................................... iv
LIST OF TABLES ........................................................................................................... viii
LIST OF FIGURES ........................................................................................................... ix
Chapter 1. Introduction ...................................................................................................... 1
Chapter 2 Literature Review .............................................................................................. 3
2.1 Working Mechanisms of Lithium-Ion Batteries ...................................................... 3
2.2 Lithium Ion Battery Negative Electrodes................................................................. 4
2.3 Electrochemical Techniques for LIB Research ........................................................ 8
2.3.1 Cyclic Voltammetry .......................................................................................... 8
2.3.2 Galvanostatic Cycling........................................................................................ 9
Chapter 3 Whisker Formation on A Thin Film Tin Lithium-Ion Battery Anode ........... 13
3.1 Summary ................................................................................................................ 13
3.2 Introduction ............................................................................................................ 13
3.3 Experimental Section ............................................................................................. 14
3.3.1 Thin Film Preparation ...................................................................................... 14
3.3.2 Electrochemical Measurements ....................................................................... 14
3.3.3 Characterization ............................................................................................... 15
v
3.4 Results and Discussion ........................................................................................... 15
3.5 Conclusions ............................................................................................................ 18
Chapter 4 Crack Pattern Formation in Thin Film Lithium-Ion Battery Electrodes ........ 23
4.1 Summary ................................................................................................................ 23
4.2 Introduction ............................................................................................................ 23
4.3 Experimental Section ............................................................................................. 25
4.3.1 Preparation of Thin Films ................................................................................ 25
4.3.2 Electrochemical Measurements ....................................................................... 25
4.3.3 Materials Characterization ............................................................................... 25
4.4 Modeling ................................................................................................................ 26
4.5 Results and Discussion ........................................................................................... 28
4.6 Conclusions ............................................................................................................ 33
Chapter 5 Liquid Metal Alloys as Self-Healing Negative Electrodes for Lithium Ion
Batteries ........................................................................................................................... 43
5.1 Summary ................................................................................................................ 43
5.2 Introduction ............................................................................................................ 43
5.3 Experimental Section ............................................................................................. 45
5.3.1 Cell Assembly.................................................................................................. 45
5.3.2 Electrochemical Measurements ....................................................................... 45
vi
5.3.3 Materials Characterization ............................................................................... 46
5.4 Results and Discussion ........................................................................................... 46
5.5 Conclusions ............................................................................................................ 49
Chapter 6 Potentiostatic Intermittent Titration Technique (PITT) for Electrodes
Governed by Diffusion and Interfacial Reaction ............................................................. 57
6.1 Summary ................................................................................................................ 57
6.2 Introduction ............................................................................................................ 57
6.3 Thermodynamics and Electrochemistry ................................................................. 59
6.4 Analytic Solutions .................................................................................................. 61
6.5 Experimental .......................................................................................................... 65
6.5.1 Sample Preparation .......................................................................................... 65
6.5.2 Electrochemical Characterization .................................................................... 66
6.6 Results and Discussion ........................................................................................... 66
6.7 Conclusions ............................................................................................................ 68
6.8 Appendix ................................................................................................................ 68
6.8.1 List of Symbols ................................................................................................ 68
6.8.2 Derivation of The Electrochemical Biot Number Using Equivalent Circuit ... 70
Chapter 7 Potentiostatic Intermittent Titration Technique (PITT) for Electrodes
Governed by Diffusion and Interfacial Reaction .............................................................. 81
7.1 Summary ................................................................................................................ 81
vii
7.2 Introduction ............................................................................................................ 81
7.3 Theory .................................................................................................................... 83
7.3.1 Governing Equations and Analytic Solutions ................................................. 83
7.3.1 Transient Current for PITT .............................................................................. 86
7.4 Experimental .......................................................................................................... 89
7.4.1 Cell Fabrication ............................................................................................... 89
7.4.2 Electrochemical Characterization .................................................................... 89
7.5 Results and Discussion ........................................................................................... 89
7.6 Conclusions ............................................................................................................ 91
7.7 Appendix ................................................................................................................ 91
7.7.1 List of Symbols ................................................................................................ 91
7.7.2 Analytic Solutions of Concentration and Current when =1.......................... 93
Chapter 8 Conclusions and Future Works ..................................................................... 103
8.1 Conclusions .......................................................................................................... 103
8.2 Future Work ......................................................................................................... 105
References ....................................................................................................................... 106
Vita .................................................................................................................................. 123
viii
LIST OF TABLES
Table 6.1 Diffusion coefficient of Li in silicon calculated by different methods. ........... 80
Table 7.1 Diffusion coefficient and interfacial kinetics of Li in MCMB (LiC12) obtained
from modified PITT. ....................................................................................................... 102
ix
LIST OF FIGURES
Figure 2.1 Gravimetric and volumetric capacities for selected alloying reactions. ......... 11
Figure 2.2 (a) Controlling profile of a CV test. (b) An example of CV of Sn vs. Li. ...... 12
Figure 3.1 First cycle galvanostatic discharge/charge curve of Sn at C/10 rate. ............. 19
Figure 3.2 (a) An SEM image of Sn after annealing at 200C for 2 hrs. (b) Surface
morphology of Sn at the stage of full lithiation. The sample stage is tilted at 80. (c)
Surface morphology of Sn after one cycle of Li insertion/extraction. The sample stage is
tilted at 60. ....................................................................................................................... 21
Figure 3.3 (a) A TEM image of a randomly selected Sn whisker after one cycle of
lithiation/delithiation. The inset SAED indicates single crystal whisker with [01-2]
direction along the axis of the whisker. (b) Enlargement of the whisker in (a). Red circle
indicates aligned structure of the amorphous shell. .......................................................... 22
Figure 4.1 An illustration of the 2-D spring-block model. The model consists an array of
hexagons, with each side of the hexagon connected to its partner by a number of elastic
springs. Here 2 springs at each side are shown. ................................................................ 34
Figure 4.2 (a) First cycle potential profile for a 500 nm amorphous Si thin film. (b)
Cycling performance of 500, 200, and 100 nm thick a-Si thin films. Solid symbols
represent discharging and open symbols represent charging. ........................................... 35
Figure 4.3 (a) An SEM image of a 500 nm a-Si film before electrochemical tests and
cracking patterns formed on a-Si thin films of different thicknesses: (b) 1000 nm thick,
after 5 cycles. (c) 500 nm thick, after 5 cycles. (d) 200 nm thick, after 10 cycles. .......... 37
Figure 4.4 Simulated crack patterns representing selected conditions. The crack to slip
ratio was fixed to be 0.5, and the number of springs per side varies. (a) =10,
x
representing 1000 nm thick film. (b) =5, representing 500 nm thick film. (c) =2,
representing 200 nm thick film. ........................................................................................ 38
Figure 4.5 A scaling relationship between the average cracked area and the film
thickness . The slop is found to be 2.16. ......................................................................... 38
Figure 4.6 Schematic of a fractured piece of a-Si during de-lithiation. There is a tensile
stress in the thin film during de-lithiation, and a friction at the interface of
active material and substrate. Formation of the pattern could be a result of natural
cracking due to cycling, or could be artificially produced to avoid further cracking of
electrodes. ......................................................................................................................... 39
Figure 4.7 An SEM image showing surface morphology of 500 nm thick Si films after
10 electrochemical cycles. ................................................................................................ 39
Figure 4.8 An SEM image showing surface morphology of 100 nm thick Si films after
10 electrochemical cycles. ................................................................................................ 40
Figure 4.9 Area-perimeter scaling for islands divided by cracks. The power law fitting
gives fractal dimensions , which is defined as the power of area to perimeter. (a) Film
thickness is 1000 nm, after 5 cycles. =2.01. (b) Film thickness is 500 nm, after 5
cycles. =1.96. (c) Film thickness is 200 nm, after 10 cycles. =1.57. (d) as a
function of film thickness. ................................................................................................ 42
Figure 5.1 Galvanostatic voltage-capacity profile of Ga at 40°C. The cycling rate was
C/50. The letters a, b, c, and d correspond to different states for the SEM images of Fig.
5.2...................................................................................................................................... 50
Figure 5.2 Morphology changes of Ga with cycling. Figures are taken from different
states of cycling depicted in Fig. 5.1: (a) Ga before cycling, (b) after full lithiation, (c)
cracks formation in Ga-Li alloy during delithiation, and (d) cracks are self-healed by the
solid-liquid transformation................................................................................................ 52
xi
Figure 5.3 Discharging voltage-capacity profiles of liquid Ga (40°C) and solid Ga (20°C)
at C/2 rate. ......................................................................................................................... 53
Figure 5.4 Electrochemical data for the liquid Ga electrode. (a) Rate dependence of
discharging voltage-capacity profiles of Ga at 40°C. The cell was charged to 0.005 V at
C/20 rate before each discharging. (b) Capacity versus cycle number for liquid Ga at
40°C. The charging rate was C/20, and the discharging rate was C/5. ............................. 54
Figure 5.5 Nyquist plot of EIS of liquid (40°C) and solid (10°C) Ga at 0.890 V vs. Li/Li+.
Inset shows the magnified impedance spectra at high frequency. .................................... 55
Figure 5.6 Schematic of morphology changes in liquid electrode during cycling. (a)
Liquid metal electrode on a solid substrate before electrochemical cycling. (b) Liquid
solidifies and expands during lithiation. (c) Cracking occurs in solid mainly during
delithiation. (d) Electrode returns to the liquid state during delithiation. Cracks are self-
healed by the solid-to-liquid phase transformation. .......................................................... 56
Fig. 6.1 Concentration profiles under PITT operation at short times, i.e. , for
different electrochemical Biot numbers. (a) =100. (b) =5. (c) =0.05. ...................... 74
Fig. 6.2 Dimensionless transient current vs. time at short times with various
electrochemical Biot numbers. .......................................................................................... 75
Fig. 6.3 Concentration profiles under PITT operation at long times, i.e. , for
different electrochemical Biot numbers. (a) =100. (b) =5. (c) =0.05. .................... 77
Fig. 6.4 Dimensionless transient current vs. time at long times with various
electrochemical Biot numbers. .......................................................................................... 78
Fig. 6.5 Plot of transient current vs. at short time. ............................................. 79
Fig. 6.6 Exponential dependence of current on time at long time. .................................. 79
xii
Fig. 7.1 Concentration profiles in an individual particle under PITT operation at short
times ( ) for different electrochemical Biot numbers. (a) =50. (b) =5. (c)
=0.05. .............................................................................................................................. 96
Fig. 7.2 Concentration profiles in an individual particle under PITT operation at long
times ( ) for different electrochemical Biot numbers. (a) =50. (b) =5. (c)
=0.05. .............................................................................................................................. 98
Fig. 7.3 Dimensionless transient current vs. time at short times ( ) with
various electrochemical Biot numbers. ............................................................................. 99
Fig. 7.4 Dimensionless transient current vs. time at long times ( ) with
various electrochemical Biot numbers. ............................................................................. 99
Fig. 7.5 Quasi-equilibrium potential-composition profile of Li-graphite (MCMB)
obtained by potentiostatic Coulombic titration. .............................................................. 100
Fig. 7.6 Plot of transient current vs. at short times. ......................................... 101
Fig. 7.7 Exponential dependence of current on time at long times................................ 101
1
Chapter 1. Introduction
Since the commercialization in early 1990s by Sony, Lithium-ion batteries (LIBs) have
been widely used in modern society as portable energy sources due to their high
operation voltage, high energy and power densities, and stable cycling performance.
Particularly, LIBs are used to replace other secondary batteries, including nickel-metal
hydride batteries, lead-acid batteries, and alkaline batteries, to power electronic devices,
medical devices, portable power tools, and more recently, hybrid and pure electric
vehicles [1-3].
A typical LIB consists of a positive electrode, a negative electrode, and a porous
separator immersed in ionically conducting liquid electrolyte. With the rapid increase of
demands, current commercial LIBs are unable to fulfill the energy and power
requirements of products, especially hybrid and pure electric vehicles. Thus, advanced
electrode materials with higher specific capacities (mAh g-1
) and capacity densities (mAh
mL-1
) are required. Commercially used negative electrode material, graphite, has already
reached its theoretical and engineering limits. There are several elements and alloys
possible for negative electrodes of LIBs due to their high theoretical capacities, such as
silicon (Si), tin (Sn), and germanium (Ge). These advanced negative electrode materials
suffer severe volume expansion and contraction upon lithiation and de-lithiation, which
leads to cracking and fracture in electrodes, and further leads to loss of electric
conduction and capacity fading of the electrodes.
Numerous efforts have been made to avoid mechanical degradation of LIB electrodes
upon extended cycling. Naonstructuring the electrodes has been shown to effectively
enhance the cycling performance of LIB electrodes. Low stress generated in
nanostructured materials during cycling is believed a reason for better cycle life. Alloying
the active materials with inactive elements or other active elements is another method to
practically extend the life of the electrodes. The inert elements act as buffer components
and absorb mechanical deformation. Various types of conducting additives and binders
2
are developed for LIB electrodes, which can practically enhance the conductivity of
electrodes and connect the powders (or particles) upon small volume change.
In this dissertation, we focus on understanding the mechanical degradation of advanced
LIB anodes, electrode/electrolyte interfacial kinetics, and diffusion of lithium in
electrodes. The purposes of this dissertation include (1) fundamental understanding of the
mechanical behavior, especially degradation mechanisms, of LIB electrodes, (2)
developing strategies to avoid degradation and cracking of electrodes, and (3)
quantitative measuring and understanding lithium diffusion in electrodes and interfacial
reaction kinetics.
Chapter 1 gives a brief introduction of the background and the purpose of this dissertation.
Chapter 2 provides the literature review of the state-of-art LIB negative electrodes, their
failure mechanisms, and possible solutions. Common electrochemical testing procedures
for LIB research are also introduced and discussed. Chapter 3 reports an observation of
whisker formation in Sn electrodes as a result of electrochemical cycling. Chapter 4
discusses experimental study of cracking pattern formation in thin-film amorphous-Si
electrodes during cycling. A simulation tool for cracking patterns is introduced which
captures the essential feature of cracking patterns. We also provide strategies to avoid
cracking in thin-film LIB electrodes. Chapter 5 shows the concept of using lithium-active
liquid metal as self-healing LIB electrodes by an example of liquid gallium (Ga).
Mechanical degradation as a failure mechanism of LIB electrodes can be eliminated by
solid-to-liquid phase transformation of electrodes. Chapter 6 proposes a modified
potential intermittent titration technique (PITT) as an electroanalytical technique which
can be used to determine the interfacial reaction rate and diffusion coefficient
simultaneously. Chapter 7 extended this modified PITT to composite electrodes where
active particles are of spherical geometry. Chapter 8 summarizes this dissertation with an
outline of future research opportunities.
3
Chapter 2 Literature Review
2.1 Working Mechanisms of Lithium-Ion Batteries
A battery consists one or more cells that convert chemical energy into electrical energy.
A battery is usually composed of a positive electrode (cathode) and a negative electrode
(anode) separated by ionically conducting and electronically insulating electrolyte. The
electromotive force of a battery, , is determined by the Gibbs free energy by
(2.1)
where is the charge number ( =1 for lithium ions) and is Faraday’s constant. A
voltage of a cell is determined by the chemical potential difference between the positive
and negative electrodes. For LIBs, the voltage of a cell is determined by the difference of
chemical potentials of lithium atoms in positive and negative electrodes. Eq. (2.1) gives
the theoretical voltage or open circuit voltage (OCV) of a cell.
The positive electrode materials of LIBs are usually layered-type lithium metal oxides
(for example, LiCoO2) [4-6], olivine-type lithium metal phosphates or silicates (for
example, LiFePO4 and LiFeSiO4) [5, 6], spinel-type lithium metal oxides (for example,
LiMn2O4), or conversion-type alloys. The negative electrode materials of LIBs are
usually composed of various types of graphite [7-9], Si [10, 11], Sn [10, 12, 13], Ge [14,
15], TiO2 [16], or their alloys or composites. During operation, the lithium-ion containing
electrolyte transports lithium ions back and forth.
Half cells are usually used for fundamental research of LIB electrodes. The term half cell
refers to a cell consisting of a single electrode (either positive or negative) as the working
electrode (WE) and pure lithium metal as the counter electrode (CE). In this type of cells,
CE is also used as reference electrode (RE), whose electrochemical potential does not
change and is set to be zero.
4
2.2 Lithium Ion Battery Negative Electrodes
Since the late 1980s [17], graphite materials have been used as negative electrodes for
LIBs. There are different kinds of graphitic electrode materials, such as natural and
artificial graphite, mesocarbon microbeads (MCMB), and highly disordered or
amorphous carbons [8, 18, 19]. The theoretical specific capacity (charge per unit mass) of
graphite is 372 mAh g-1
and the theoretical capacity density (charge per unit volume) is
840 mAh mL-1
, calculated from the final product of lithiated graphite, LiC6. The reaction
of graphite during lithiation and de-lithiation can be summarized as
(2.2)
The layered structure of graphite naturally provides space to store lithium atoms. As a
result, the volume change of graphite upon cycling is less than 10% [8, 19] and the stress
is in the order of several hundred MPa [20], one order of magnitude lower than that of
alloy electrodes [21, 22]. Thus, commercial electrochemical-grade graphite delivers
stable capacity over several hundred cycles due to low volume change and low stress.
Alternative materials for negative materials of LIBs include pure elements, alloys, metal
oxides, and composite materials. There are many elements which have much higher
specific capacities than graphite. For example, the theoretical specific capacity of Si is
3579 mAh g-1
[23], which is the highest among all the elements for negative electrodes
except for pure Li metal itself. Figure 2.1 shows selected elements for LIB negative
electrodes [24]. These elements react with Li and form alloys where the atomic ratio of Li
to the active element can be as large as 4.4. Besides pure elements, some metal oxides
react with Li metal, such as TiO2 [16], NiO, and Li4Ti5O12 (LTO) [16, 25, 26], and can
also be used as negative electrodes.
The reaction mechanisms, electrochemical behavior, and cycling performance of pure
element type negative electrodes are similar. Here, we take Si as an example to
demonstrate the main issues and obstacles for their applications. Si has attracted
significant attention of researchers mainly because of its highest theoretical capacity. It is
5
reported that during lithiation, Si and Li form alloys including Li12Si7, Li7Si3, Li13Si4, and
Li17Si5 [23, 27, 28]. It is well accepted that bulk Si hardly delivers useful capacity [11, 29,
30], mainly because of the large volume expansion of Si during cycling which can be as
large as 370% [29, 31], as well as the associated large diffusion-induced stress (DIS) [21,
22]. Dahn et al. [27] and Obrovac et al. [23] have separately reported that crystalline Si
undergoes amorphization during lithiation, and keeps amorphous during cycling unless
the electrodes are over lithiated [32]. Sn forms Li17Sn4 upon full lithiation [18, 33], which
gives a specific capacity of 992 mAh g-1
. Similar to Si, the cycle life of bulk Sn is short
(i.e., 10 cycles [12]) because of large volume expansion and high DIS [12, 18].
In order to overcome the issue of pulverization and capacity fading of electrodes,
different methods have been applied in order to utilize the advanced negative materials.
These strategies can be divided into four categories, including reducing the dimensions of
active material, alloying the elements with inert or another active components, utilizing
conducting components and binders for composite electrodes, and surface modification
of electrode materials.
Nanostructuring the electrode materials is an effective way to enhance the reversible
capacity and extend the cycle life of LIBs. Various nanostructured electrodes have been
reported to deliver improved performance, including thin films [14, 34, 35], nanowires
[36], nanoporous structures [37, 38], nano-patterned electrodes [39, 40], and other nano-
shaped materials [41, 42]. Most of the nanostructured electrodes showed improved
reversible capacity upon extended cycling. For example, Graetz et al. showed improved
cycling performance of Si thin-films over nano-crystals [35]. Cui et al. demonstrated
extended cycle life and high capacity of Si nanowires directly grew on stainless steel
current collectors [36]. Cho et al. compared cycling performance of Si nano particles
ranging from several to tens of nanometers, and demonstrated excellent capacity retention
using ~5 nm Si nano particles [30]. Xiao et al. studied cycling performance of patterned
Si, and showed stable capacity over 40 cycles where the average width of the square
patch is about 7.6 μm [39]. A low average diffusion-induced stress in patterned electrodes
is believed the reason for improved capacity retention [43]. Similar phenomena were
6
observed on patterned thin-film Sn-Co-C composite electrodes where the pattern size is
about 7.5 μm [40]. It is believed that the enhanced performance of nanostructured
materials is mainly due to voids which occupy a large portion of nanostructured
electrodes, and provide space for volume expansion during lithiation. Cheng et al.
showed that the stress level and maximum stress in nano-structure materials is lower than
that in bulk materials because of surface effects [44, 45]. Also, the power performance
(cycling performance under high rates) of nano-structural electrodes is usually good,
because the average diffusion distance for lithium is shortened and a large surface area
provides sites for interfacial reactions. On the other hand, there are serious drawbacks for
nanostructured LIB electrodes. Most importantly, the large surface area of nanostructured
materials requires formation of a large amount of solid electrolyte interphase (SEI) upon
lithiation, which consumes lithium ions from the lithium-salt-based non-aqueous
electrolyte [46-48]. The formation of SEI is largely irreversible and SEI does not
decompose readily into lithium ions upon de-lithiation [46, 47]. As a result, the
performance of a full cell using nano-structured electrodes will be limited because of
limited amount of lithium ions and electrolyte. A majority of previous academic
publications are based on results of half-cells, where pure lithium metal is used as the
counter electrode and the amount of lithium ions can be considered infinite. Besides SEI,
the packing density, capacity and energy densities of nano-structured electrodes are low
due to extra space. The cost of nanostructured electrodes is high due to the usually
complicated fabrication procedures.
Alloying the active materials with other active or inert materials is another effective way
to extend the cycle life of LIBs. For example, various alloys of Si, MxSi, are produced
which show better performance, where M can be Ag [49], Mg [50, 51], Ca [52], carbon
[53-55], Zn [56], as well as transition metals such as Co, Fe, Mn, Ni, and Co [57-61].
Metal oxides also delivers improved cycling performance, such as SiO [62, 63], SnOx
[64-69], and GeO [42]. It is believed that the inert components remain unchanged during
cycling, and thus the overall stress of the whole electrode is lowered. Furthermore, inert
elements can act as “buffer” components which absorb strain energy of the active
7
components. On the other hand, inert components add mass and volume to the electrodes,
and thus lower the specific capacity and capacity density of the electrodes. Usually the
first-cycle Columbic efficiency is low due to irreversible reactions of Li and inert
elements.
Binders and conducting additives are necessary for commercial LIB electrodes, where the
active materials are in the form of powders. For current commercial LIBs using graphite
as the negative electrodes and LiCoO2 as the positive electrodes, polyvinylidene fluoride
(PVDF) is used as the binder and carbon black is used as the conducting additives. It has
been reported that sodium carboxymethyl cellulose (NaCMC) or lithium carboxymethyl
cellulose (LiCMC) can be used as the binder for Si and other high capacity composite
electrodes with improved capacity retention [70-72]. However, the reason is still a
mystery because CMC salts are essentially brittle. Other kinds of conducting additives,
such as carbon nanotubes (CNT) [73, 74], have been shown to improve the performance
of composite electrodes.
Recently, surface modifications, particularly surface coating of electrode materials, has
been shown to improve the performance of LIB electrodes. The coating materials for LIB
electrodes are versatile, including carbon [75-77], metals (i.e., Ag, Sn) [78-80], and metal
oxides (i.e., Al2O3, TiO2) [81-83] and other ceramics (i.e., AlF3, LIPON) [84-86]. The
mechanisms of surface modification during cycling are not well understood. Usually, it is
believed that surface coating has a strong effect on the surface chemistry, morphology,
structure, and properties of surface film (SEI for negative electrodes). Further, surface
modification may suppress metal dissolution by reacting with residual trace-amounts of
HF in the electrolyte. Surface coatings can also change the interfacial kinetics, improve
surface conductivity, and act as mechanical protecting layers.
In general, nano-structuring and alloying are effective methods to enhance the capacity
retention and cycling performance of LIB electrodes by reducing the stress level during
lithiation and de-lithiation. However, efforts have to be made to overcome the issue of
large amount of SEI formation and surface attack from the electrolyte due to the
8
relatively large ratio of surface area to volume. Surface modification is effective in
suppressing the formation of SEI by changing surface chemistry. Practically, in order to
produce LIB electrodes with high capacity and power density, good cycling performance,
and reasonable packing density, multiple strategies mentioned above are needed. For
example, Simon et al. electrodeposited Sn on current collectors of Cu nano-rods, and
showed improved capacity at more than 500 cycles [41]. It was demonstrated that
composite electrode consisting of nano sized Sn and C had stable reversible capacity of
500 mAh g-1
up to 200 cycles [87, 88]. More recently, Cui et al. reported that double wall
Si nanotube delivers capacity of more than 1000 mAh g-1
after 6000 cycles of
charge/discharge [89].
2.3 Electrochemical Techniques for LIB Research
Electrochemical and electroanalytical techniques can provide useful information about
thermodynamics and kinetics of electrochemical systems, including equilibrium potential
of reactions and types of reactions occurring in electrodes, reaction kinetics,
thermodynamics information, and lithium diffusion in electrodes and electrolytes.
Typically, electrochemical techniques require static or dynamic control of voltage or
current while monitoring the change of both voltage and current. In this section, major
electrochemical techniques used in this dissertation, including cyclic voltammetry and
galvanostatic cycling, are introduced and discussed.
2.3.1 Cyclic Voltammetry
Cyclic voltammetry (CV) is one of the most commonly used electrochemical techniques
to investigate the chemical reaction types, Nernstian (reversible) or non-Nernstian
(irreversible) behavior of redox couples, formation potentials, and reaction mechanisms.
CV is convenient and efficient in obtaining qualitative information, though it is usually
not a good technique for quantitative studies.
In a CV test, the potential of the system is swept linearly towards a peak position, and
then returned to the initial value linearly. The procedure can be repeated multiple times.
9
During the potential sweep, current is monitored by a potentiostat. An illustration of a CV
controlling profile is shown in Fig. 2.2 (a).
The result of CV experiments is usually plotted as current vs. applied potential. An
example of Sn vs. Li is shown in Fig. 2.2 (b). The information of this CV test include (a)
irreversible reactions (the sharp region near 2.0 V, which is a result of reaction between
lithium and residual oxygen, moisture, and other impurities in electrolyte), (b) reversible
phase transformations (the peaks in Fig. 2.2 (b), which represents phase transformations
of Li-Sn alloys with different compositions), and (c) potential of oxidation and reduction
reactions (peak potentials).
2.3.2 Galvanostatic Cycling
Galvanostatic cycling is a very important electrochemical technique for LIB research,
which provides charging and discharging profiles for LIBs under practical applications.
In a galvanostatic cycling test, a cell is charged and discharged galvanostaticlly (constant
current) between upper and lower voltage limits.
The upper and lower voltage limits are determined by the Gibbs free energy of the
electrode materials and their products during lithiation. For alloy-type negative electrodes,
the lower limits are practically 10 to 50 mV, and the upper limits are practically 1 to 2 V,
depends on the type of alloys. The lower limits are chosen to be higher than 0 V vs.
Li/Li+ because at low potentials lithium tends to deposit on electrode surface, which
eventually causes the growth of lithium dendrites, causing safety issues.
The applied current is directly related to the power output of the electrode. Usually “C-
rate” is used to define the cycling rate of LIBs, where C is defined as hours per
charge or discharge. Practically C/10 or C/5 is considered slow cycling, though it is non-
equilibrium.
10
There are three ways of plotting the results of galvanostatic cycling, namely potential-
capacity profile, differential potential-capacity profile, and cycling performance. Plenty
of examples are given in later chapters of this dissertation.
From galvanostatic cycling, we can obtain information about phase transformations in
electrodes under different kinetics, rate performance, structure of the intermetallics
during lithiation (crystalline or amorphous), potential range for practical use, and cycle
life of LIBs.
11
Figure 2.1 Gravimetric and volumetric capacities for selected alloying reactions.
Adapted from Reference [24]. Copyright © The Royal Society of Chemistry 2007.
12
(a)
(b)
Figure 2.2 (a) Controlling profile of a CV test. (b) An example of CV of Sn vs. Li.
13
Chapter 3 Whisker Formation on A Thin Film Tin Lithium-Ion Battery Anode 1
3.1 Summary
Tin (Sn) is a candidate material for negative electrodes of lithium-ion batteries (LIBs)
because of its high theoretical energy capacity. In this chapter, we show an observation of
Sn-whisker growth on Sn-thin films after lithiation and de-lithiation. The compressive
stress generated by electrochemical lithiation of the Sn-thin films is likely the driving
force for the growth of the Sn whiskers. Attention should therefore be paid to the issue of
Sn whisker growth for Sn-based electrodes since Sn whiskers may penetrate through the
separator, and short-circuit the electrochemical cell.
3.2 Introduction
LIBs are widely used as power supplies for various electronic devices due to their high
energy and power densities. The growing demands for electronic devices, portable tools,
and hybrid and all-electric vehicles require batteries with higher capacity and longer
durability. Commercial graphite anodes used in LIBs have good cycling behavior with a
capacity of 372 mAh g-1
[8]. Sn is one of the prominent materials for the negative
electrodes of LIBs because of its high gravitational and volumetric capacities (992 mAh
g-1
and 7262 mAh cm-3
, respectively [24]). However, the volume change from pure Sn to
its fully lithiated phase (Li4.4Sn) is approximately 260% [31]. This large volume change
results in fracture and pulverization of the active material and poor cycling ability, which
hinders its application as an electrode material. The large stress and strain created by
volume expansion and contraction are the cause of cracks and fracture of the active
materials [90-92].
1 Reproduced from Journal of Power Sources, 196 (3): 1474-1477 (2011). Copyright ©
Elsevier B.V. 2010.
14
The electrochemical performance of Sn based alloys, such as Sn-Cu [93-95], Sn-Ni [87,
95], Sn-Zn [96], and Sn-Co [97, 98], has been studied. Capacity retention is improved
due to the formation of active/inactive structure in these Sn alloys. The cycling
performance of materials can also be enhanced by using nano-scale structures [18, 99,
100].
Furthermore, safety is a key issue for LIBs. But, there are few reports on the safety
studies of Sn-based electrodes. In this work, we report the first observation of Sn-whisker
formation after lithiation and delithiation. The Sn whiskers may be a safety concern for
Sn-based LIBs.
3.3 Experimental Section
3.3.1 Thin Film Preparation
Sn thin films were deposited on 0.5 mm thick stainless steel discs by radio frequency (RF)
magnetron sputtering using an Advanced Energy system. A pure Sn target (99.998%,
Kurt J. Lesker) of 25.4 mm diameter was used in the sputtering. Pre-sputtering was
carried out in ultra-high-purity argon (Ar, 99.999%, Scott-Gross) at 50 W for 5 mins to
remove any oxides and contaminations on the Sn target surface. Sn sputtering was
performed in Ar with a working pressure of 3 Pa and a power of 30 W. The substrate was
kept at room temperature of about 23°C during sputtering. The film thickness was
recorded by a quartz crystal microbalance thickness monitor (Inficon) during sputtering,
and was examined by a Dektak 3030 profillometer (Veeco) after sputtering. Immediately
after sputtering, samples were annealed at 200°C under Ar atmosphere for 2 hours to
remove internal stresses generated during the sputtering.
3.3.2 Electrochemical Measurements
The electrochemical performance of the as-prepared Sn thin films was evaluated using
2025-type coin cells (Hohsen). The stainless steel substrate served as the current collector
to obtain a uniform current distribution. Pure lithium foils (99.9%, Sigma Aldrich) were
15
cut into proper size and used as the counter electrode. Poly-propylene woven separators
(Celgard 3501) were used in the coin cells. 1 M LiPF6 in ethylene carbonate / dimethyl
carbonate (EC/DMC, 1:1 by vol.) was used as the electrolyte (Novolyte). Electrochemical
performance was conducted using a VMP3 multi-channel potentiostat/galvanostat (Bio-
Logic). Galvanostatic cycling of the cells was carried out at a rate of C/10 between 1.2 V
and 0.02 V.
3.3.3 Characterization
After cell disassembly, the Sn thin films were cleaned using DMC (99%, Alfa Aesar),
and then examined by scanning electron microscope (SEM, Hitachi S-4300 at 3 kV) and
field emission transmission electron microscope (FETEM, JEOL 2010F at 200 kV).
3.4 Results and Discussion
Before performing the first galvanostatic cycle, the Sn electrode was rapidly lithiated to
1.2 V relative to pure Li to avoid the anomalous irreversible capacity during initial
lithiation of Sn [101]. The initial galvanostatic cycle within the 0.02 V – 1.2 V potential
window is shown in Fig. 3.1. The Sn thin film electrode had a reversible capacity of 725
mAh g-1
during the first cycle. The irreversible capacity of 155 mAh g-1
at the first cycle
was mainly due to the formation of solid electrolyte interphase (SEI) on the electrode,
which consumed Li ions from the electrolyte [47]. After removing the effect of SEI on
the initial lithiation capacity, the calculated Li to Sn atomic ratio is 3.2:1. This ratio
suggests a combination of Li-Sn phases which do not have a long-range ordered structure
[13]. The theoretical capacity of Sn (992 mAh g-1
) is calculated based on the formation of
the ultimate phase of lithiation, Li4.4Sn. However, it is difficult for Sn to be fully lithiated
to the state of 4.4 Li atoms per Sn atom at room temperature, due to the limited
diffusivity of Li atoms in Sn and LixSny phases, and due to the non-equilibrium
electrochemical condition. Our results of Sn cycling show that even at a relatively slow
rate of C/70, Li3.8Sn formed after full lithiation. This observation is consistent with a
previous study [13].
16
To compare the structural change of Sn-thin films due to the electrochemical cycling, the
morphology of 500 nm Sn films before and after electrochemical lithiation, and after
delithiation is shown in Fig. 3.2. During sputtering, Sn thin films were not uniform due to
the high mobility of Sn atoms. Though the surface of the as-prepared Sn thin film was not
uniform, there was no whisker growth observed after the sputtering. Furthermore, no
whisker formation was observed after leaving the Sn thin films in ambient environment
for 30 days. This indicates that the internal stress was negligible in the Sn-thin films after
annealing. However, after lithiation, the formation of long Sn whiskers and large Sn
hillocks was observed, as shown in Fig. 3.2 (b). The average number of Sn whiskers per
unit area was calculated to be 1306 ± 280 in 1 mm2. The length of the Sn whiskers ranges
from several µm to 30 µm, with a diameter of 150 to 300 nm. In addition, cracks formed
on Sn thin films after the first lithiation/delithiation cycle, as shown in Fig. 3.2 (c).
Fig. 3.3 (a) and (b) show the FETEM image of a randomly selected whisker after one
cycle of lithiation/de-lithiation. The sharp edges and corners of the whisker in Fig. 3.3 (a)
and the periodic atomic structure in Fig 3.3 (b) indicate that the whisker is a single crystal,
whose crystal structure was confirmed by selected area electron diffraction (SAED, inset
of Fig. 3.3 (a)) to be body-centered tetragonal (β-Sn) with the [01-2] direction along the
axis of the whisker. There is an amorphous layer covering the crystalline whisker, which
may be the remaining SEI layer [102] after sample cleaning by DMC or an oxide layer
[103, 104] formed during the TEM sample preparation. While the majority of the layer is
amorphous, a small portion shows aligned structure, suggesting crystallization of SEI as
indicated by the circle in Fig. 3.3 (b).
Sn-whisker formation and growth have been extensively studied, and Sn whiskers have
been observed on electrodeposited and sputtered Sn thin films [105-107]. Sn whiskers
usually form due to stresses which are generated during solid-state reaction of Sn and the
Cu substrate to form intermetallic compounds, such as Cu6Sn5 [107-109]. Generally,
whisker growth is a result of the compressive stress along the thickness direction of the
film by a “squeeze out” mechanism [107, 110]. A related phenomena is the stress-
induced growth of nanowires caused by hundreds of MPa of compressive stress incurred
17
during film deposition [111]. Recently, the effect of aging time on Sn-whisker growth
from thin films and their anode behaviors in LIBs have been studied [112].
In the present experiment, intermetallics do not form between the Sn thin film and the
stainless steel substrate. The formation of Sn whiskers is likely caused by the lithiation-
induced stress. During lithiation, Li and Sn form LixSn phases, which create large
compressive stress in the Sn film because of volume expansion and constrain of the
substrate. Our results of stress measurement using a home-built laser-curvature device
show that the compressive stress in Sn thin films is about 700 MPa during lithiation. This
compressive stress, which is higher than what is usually required for Sn whisker growth,
leads to the “squeeze out” of Sn atoms form Sn whiskers during lithiation.
Pure Li metal has several advantages over other anode materials for LIBs, including large
specific capacity, and high energy density. However, a detrimental phenomenon that
impedes the application of pure Li metal as anodes of LIBs is the morphological change
of Li metal and the formation of Li dendrites [1, 113, 114] during electrochemical cycling.
The Li dendrites can penetrate through the separator, short-circuit the electrochemical
cell, and thus causes serious safety problems. Safety is more prominent in the application
of large number of cells, such as hybrid and all-electric vehicles, than individual cells,
since the probability of failure of a battery pack consisting of many individual battery
cells in series is proportional to the number of cells. Problems with any individual cell
could damage the whole power supply.
The shear moduli of pure Sn and pure Li at room temperature are 19.0 GPa [115] and 4.2
GPa [116], respectively. It is expected that the strength of single crystal Sn whiskers is
much greater than single crystal and polycrystalline Li dendrites, because the theoretical
strength of a single crystal is approximately 1/10 of its shear modulus. Similar to the
lithium dendrites, Sn whiskers may also penetrate through the porous polymer separator
and cause a short-circuit of the LIB. Actually, the initial interest in study on Sn whiskers
was raised by the fact that Sn whiskers formed from solders could short-circuit electronic
circuits and destroy electronic devices. The observed formation of Sn whiskers during
18
lithiation of Sn-thin film electrodes suggests the need for more detailed studies of
whisker formation in alloy electrodes consisting of low melting point elements, such as
Sn, as well as the effects of whiskers on the safely of LIBs.
3.5 Conclusions
In this chapter, we report the first observation of Sn whisker growth after lithiation of Sn
thin film electrodes. The formed whiskers are pure Sn single crystal. The high
compressive stress during lithiation is likely the driving force for the whisker growth.
Since these whiskers may short-circuit the cells, more detailed studies of lithiation-
induced whisker growth and their safety implications are needed for Sn-based electrodes
in LIB applications.
19
Figure 3.1 First cycle galvanostatic discharge/charge curve of Sn at C/10 rate.
20
(a)
(b)
21
(c)
Figure 3.2 (a) An SEM image of Sn after annealing at 200C for 2 hrs. (b) Surface
morphology of Sn at the stage of full lithiation. The sample stage is tilted at 80. (c)
Surface morphology of Sn after one cycle of Li insertion/extraction. The sample stage is
tilted at 60.
22
(a)
(b)
Figure 3.3 (a) A TEM image of a randomly selected Sn whisker after one cycle of
lithiation/delithiation. The inset SAED indicates single crystal whisker with [01-2]
direction along the axis of the whisker. (b) Enlargement of the whisker in (a). Red circle
indicates aligned structure of the amorphous shell.
23
Chapter 4 Crack Pattern Formation in Thin Film Lithium-Ion Battery Electrodes 2
4.1 Summary
Cracking of electrodes caused by large volume change and the associated lithium
diffusion-induced stress during electrochemical cycling is one of the main reasons for the
short cycle life of lithium-ion batteries using high capacity anode materials, such as Si
and Sn. In this chapter, we study the fracture behavior and cracking patterns in
amorphous Si thin film electrodes as a result of electrochemical cycling. A modified
spring-block model is shown to capture the essential features of cracking patterns of
electrode materials, including self-similarity. It is shown that cracks are straight in thick
films, but show more wiggles in thin films. As the thickness of film decreases, the
average size of islands separated by cracks decreases. A critical thickness bellow which
material would not crack is found for amorphous Si films. The experimental and
simulation results of this work provide guidelines for designing crack free thin-film
lithium ion battery electrodes during cycling by patterning the electrode and reducing the
film thickness.
4.2 Introduction
The rapid development of portable electronics, hand tools, and electric vehicles demands
ever higher capacity and more durable rechargeable batteries, in particular, lithium-ion
batteries (LIBs). New battery electrode materials with higher capacity than the
commercially available graphite and LiCoO2 are being explored extensively. The most
promising materials for the anodes of LIBs are Si, Sn, Ge, and their alloys. However,
these materials usually show a much shorter cycle life compared to commercial graphite
electrodes. The main cause for the poor cycling behavior is fracture of electrodes, which
2 Reproduced from Journal of The Electrochemical Society, 158 (6): A689-A694 (2011).
Copyright © The Electrochemical Society 2011.
24
is the result of large volume change and the associated large diffusion-induced stress
(DIS) [90, 117].
Cracking during electrochemical lithiation and de-lithiation has been observed in
electrode materials such as Si [118], Sn [18, 119], Si-Sn alloys [31], Ni-Sn alloys [119,
120], and Ge [14]. Cracking patterns have also been observed and studied in other fields
of inquiries, including deposition of amorphous Si film [121], drying of clays [122] and
polymer paints [122], glasses [123], and aging of woods [124]. The ubiquitous and
intriguing cracking patterns have generated broad interest in understanding the
mechanisms of crack evolution and pattern formation in a number of fields. Several
models have been proposed to simulate the cracking behaviors caused by drying and
other physical and chemical shrinkage processes [122, 124-126]. Sadhukhan et al.
proposed a one-dimensional spring chain model to mimic the cracking behavior in drying
of polymer on different substrates [127]. Nag et al. developed this model to simulate two-
dimensional cracking patterns in polymer with additives [122]. Leung et al. developed a
simple two-dimensional spring-block model which captured the essential features of
cornstarch drying successfully [125]. Valette et al. developed a three-dimensional model
to dynamically simulate the cracking on surface of a desiccating crusted soil [126]. In
addition, finite element analysis has been applied to simulate fractures by shrinkage in
various objects by several groups [128, 129].
In this chapter, we study crack pattern formation in amorphous Si (a-Si) thin film
electrodes as a result of electrochemical lithiation and delithiation cycles. We also present
a modified spring-block model to simulate crack pattern formation in thin film LIB
electrodes. This work provides guidelines for designing LIB electrodes that do not crack
during cycling.
25
4.3 Experimental Section
4.3.1 Preparation of Thin Films
Amorphous Si thin films were fabricated by sputtering Si onto 0.5 mm thick 430-type
stainless steel (SS) disks in a commercial magnetron sputtering system (Advanced
Energy). Prior to the sputtering deposition, the SS disks were ground and polished using
50 nm Al2O3 colloidal to remove surface scratches which could affect crack formation. A
25.4 mm diameter target of pure Si (99.995%, Kurt J. Lesker) was used for the sputtering
deposition. Pre-sputtering was carried out at 100 W for 20 mins to remove oxides on the
Si target surface. Si thin films were deposited using a RF power supply operating at 100
W. During deposition, the chamber pressure was kept at 1 Pa of Ar. Film thicknesses
ranged from 100 to 1000 nm, as measured by a quartz crystal microbalance (Maxtek)
during deposition and by a Dektak profilometer (Veeco 3030) after deposition.
4.3.2 Electrochemical Measurements
After deposition, Si films were assembled in CR2025 coin-type half cells (Hohsen) for
electrochemical examination. Pure Li metal (99.9%, Sigma Aldrich) foils were used as
the counter electrodes. The electrolyte used was 1 M LiPF6 in ethylene carbonate /
dimethyl carbonate (EC/DMC, 50/50 by volume, Novolyte). A computer-controlled
multi-channel potentiostat (VMP3, Bio-Logic) was used to conduct the electrochemistry
measurements. The coin cells were galvanostatically cycled at a rate of C/10 at room
temperature (21°C). The high and low potential cut-offs for cycling the Si thin film
electrodes were 2.0 V and 0.002 V relative to pure Li, respectively. Discharging refers to
lithium going into Si (i.e., lithiation of Si), and charging refers to Li coming out of Si (i.e.,
de-lithiation of Si).
4.3.3 Materials Characterization
After cycling, scanning electron microscopy (SEM) imaging was performed using a
Hitachi S-4300 with an acceleration voltage of 3 kV.
26
4.4 Modeling
A computer program was implemented to simulate the cracking phenomena in thin film
electrodes. The program is based on the model proposed by Leung et al. [125] and was
modified to apply a constant strain, , as the film contracts to simulate a constant rate of
delithiation, which approximates the condition for galvanostatic charging [117]. This
model consists of a two-dimensional array of hexagons with each side of the hexagon
connected to its partner by a number of elastic springs, as illustrated in Fig. 4.1. The
purpose of this 2-D spring-block model is to keep the essential physics of cracking
behavior, while avoiding going to the details of materials behavior, which usually
complicates models largely.
Initially, the hexagons are separated by a distance of one unit, with the strain being
expressed as the length change required for a spring to have a neutral length which would
have no compressive or tensile force. The magnitude of the constant strain in the model
can be selected along with three other parameters, volume reduction , the number of
springs per side , and the ratio of cracking to slipping force . The parameter
specifies whether a spring will be broken on a side of the hexagon or if the hexagon will
slip to a new position using a threshold rule [125]. This ratio is related to the fracture
strength of the active material and adhesion strength between the active layer and the
substrate. The model is constructed using dimensionless units so it can be scaled.
Once the initial conditions are set up, the evolution of the system is determined by the
following four major steps. (1) The hexagons are displaced randomly by a small distance
and a strain is applied. (2) The force matrix is computed for all the hexagons, and for all
sides of each hexagon. While is fixed, the thresholds and are lowered until either
is exceeded. (3) If is exceeded by the forces on a bundle of springs, one spring with the
largest net force is broken. (4) If is exceeded by the net force on a hexagon, the
hexagon is moved to an equilibrium position (slipping) where the net force on this
hexagon is zero. After this step, the force matrix is recomputed for the system and steps
27
(2), (3), and (4) are repeated. The entire process takes multiple iterations to reach the final
state when the generated cracking pattern does not change further.
The above model is valid if , as in the case for mud drying [125]. A LIB anode
undergoes a large volume change during cycling [130], so that the Leung et al. model
was modified to keep the overall strain on the system small albeit constant; in other
words, the strain , and does not decrease as the system shrinks. In the condition
of constant current controlled cycling [117], there is a constant flux of Li passing through
the electrode/electrolyte interface. The constant current charging case is equivalent to
surface reaction controlled delithiation with very small electrochemical Biot Number (i.e.,
) [90, 131]. After a period, stress and strain in the electrode reach steady-state
values which are independent of time [117]. Although strain is not the same everywhere
in the electrode, the average strain is constant. To maintain this constant strain, a fifth
simulation step is added: (5) After each iteration over steps (1)-(4) an image of the
system is scanned to determine the total amount of shrinkage. From this an average
hexagon size is computed and a new neutral spring length is determined to maintain the
constant strain level. The new image is captured, and steps (2)-(5) are repeated until the
total volume change reaches the pre-set value .
The number of springs per side has the same effect as film thickness , i.e., a large
number of springs represents a thick film [125]. It is also found that and have the
same effect on crack patterns. In other words, a fixed value of gives the same
cracking pattern. In this work was fixed to be 0.5 for all simulations, which gave the
number of springs per side of 2, 3, 5, 7, and 10 corresponding to the 200, 300, 500, 700,
and 1000 nm thin films in experiments, respectively. Different values of constant strain
were found to best represent the data for differing thicknesses, with the highest 0.18
being used for the thinnest 200 nm film and the lowest of 0.08 being used for the thickest
film. This corresponds to strain being highest at the top of the film where delithiation
occurs. By using the area of the cracks in the film plane and comparing it with the
28
existing volume shrinkage data, the amount of volume reduction in the model was
adjusted to present the in-plane shrinkage observed in experiments.
4.5 Results and Discussion
Fig. 4.2 (a) shows the typical cycling performance of a 500 nm thick a-Si film. It has
been reported that phase transformation and crystallization occur during lithiation of a-Si
[27]. The final product of lithiation of a-Si is crystalline Li15Si4. After full delithiation,
material returns to the amorphous state with some residual Li15Si4 [23, 27]. However,
there is no well-defined single-phase region (vertical line) or two-phase region
(horizontal line) in the observed potential vs. charge profile, indicating that the reaction
does not fully follow the Si-Li equilibrium phase diagram under the condition used in this
experiment. The initial lithiation capacity of the 500 nm a-Si film is 3158 mAh g-1
. The
initial reversible capacity is 2680 mAh g-1
, suggesting that the material is lithiated to a
state of Li2.8Si which corresponds to 74% of theoretical capacity of Si (3600 mAh g-1
). It
is generally believed that the initial irreversible capacity is attributed to (1) the formation
of a solid electrolyte interphase (SEI) on the surface of active material [47], (2) side
reactions with impurities, and (3) partial loss of electronic contact due to expansion and
contraction of the electrode material. The second cycle reversible capacity of the a-Si
film decreases drastically to 1937 mAh g-1
(54% of theoretical capacity). The reversible
capacity fades slowly with further cycling. After 30 cycles, the 500 nm thick a-Si film
shows a reversible capacity of 1256 mAh g-1
, corresponding to 35% of its theoretical
capacity. Amorphous Si films with thicknesses of 200 nm and 100 nm show large
irreversible capacity during the first cycle, and high reversible capacity retention with
cycles (Fig. 4.2 (b)).
Similar observations of severe reversible capacity dropping during several initial cycles
of Si electrodes have been reported by other researchers [35, 132-134]. It is believed that
this loss of reversible capacity (de-lithiation capacity) at initial cycles is not due to the
formation of SEI because the formation of SEI is largely irreversible and does not
contribute to the reversible capacity [47].
29
To understand the mechanisms responsible for severe reversible capacity reduction, cells
are disassembled after electrochemical cycling and electrodes are examined by SEM. Fig.
4.3 (a) shows the morphology of the as-deposited 500 nm a-Si thin film and the cracking
patterns generated in a-Si films of selected thicknesses after lithiation/delithiation cycles.
Before cycling, there is no crack in the a-Si films. After cycling, a-Si thin films break up
into individual pieces separated by interconnected cracks. Though not connected with
each other, most of the pieces are connected to the substrate, and remain active during
lithiation and delithiation cycles. Since the SS substrate is about one thousand times
thicker than the a-Si thin film, the curvature change of the substrate during
electrochemical cycling is small. During delithiation, the removal of lithium from the
LixSi phases causes a large tensile stress, which can be as large as several GPa and
exceeds the tensile strength of a-Si [21]. Thus, interconnected, through-thickness cracks
form in the a-Si thin films after electrochemical cycling.
The generated crack patterns vary with thickness of a-Si thin films. For the 1000 nm thick
a-Si thin film (Fig. 4.3 (b)), a branch of primary cracks propagates until reaching another
branch, and all of these cracks are long and straight with a few sharp changes in direction.
These cracks show a characteristic of crack “growth”, rather than crack nucleation. The
islands separated by straight and long cracks show simple shapes. The number of crack
initiation sites or the density of cracks (total length per unit area) in the final state is
relatively small. With decreasing film thickness, cracks show more branches and wiggles,
as shown in Fig. 4.3 (c) and 4.3 (d). Although most cracks are interconnected with each
other, there are many places where cracks are unable to propagate. With more crack
initiation sites, the density of cracks is higher. The islands separated by cracks have more
complicated shapes.
Fig. 4.4 shows representative simulation results of crack patterns generated by shrinkage
using the modified spring-block model. Although this modified model is relatively simple,
it shows a good agreement with experiments, as seen by comparing Fig. 4.4 with Fig. 4.3.
When =10 (representing the 1000 nm film, Fig. 4.4 (a)), cracks are straight with a few
sharp changes in direction, and blocks separated by cracks have simple shapes. With
30
decreasing (lowering film thickness), cracks show many wiggles and islands separated
by cracks show complicated shapes. Furthermore, there are multiple sites in Fig. 4.4 (b)
and 4.3 (c) where cracks stop growing at their tips. This spring-block model can be
applied to simulate cracking in thin film LIB electrodes of other materials, such as Sn and
its alloys, by choosing adequate values for the model parameters. The model parameters
can be calibrated by experiments or theoretical calculation of the mechanical properties
of electrodes.
A scaling behavior is observed between the average cracked area and the film thickness
, as shown in Fig. 4.5. This scaling behavior suggests a power-law relation: , in
which was found to be 2.16, close to a recent prediction [125]. This relationship
predicts the average area separated by cracks under a specific condition, including
mechanical properties of active materials, rigidity of substrate, interface friction, and the
film thickness. Because the exponent is a function of film thickness, the cracking pattern
is not the same for all thin films. In fact, it shows that as the thickness decreases, the
density of cracks increases until a critical thickness below which no crack is found.
Therefore, it is reasonable to conclude that the active thin film materials would not crack
during lithiation/delithiation if the characteristic size of active material is smaller than the
predicted average cracked area . To understand this phenomenon from a point of view
of force equilibrium, a methodology similar to that proposed by Xiao et al. [39] is used.
To simplify the problem, a square pattern electrode with length of and height of is
shown in Fig. 4.6. Upon delithiation, the active material undergoes a tensile stress of .
However, the active layer cannot yield or fracture freely because of the constrain from
the substrate and the friction at the active material/substrate interface . Force
equilibrium yields
, where the interfacial force is the minimum of the
shear flow stress of the substrate and the interfacial friction strength
. For
stainless steel is about 186 MPa. Since the friction strength between metal and
silicate composite is about 40 MPa [135], the interfacial force is taken to be 40 MPa
31
as an approximation. The yield strength of lithiated Si is on the order of 1 GPa [21]. The
one-dimensional (1-D) critical size for crack initiation can be calculated by
(4.1)
The calculated 1-D cracking size is 10, 25, and 50 µm for 200, 500, and 1000 nm thin
films, respectively. Although the relationship between the calculated 1-D critical size for
cracking and film thickness does not match perfectly with experiments because of lack of
accurate data on yield stress of lithiated Si and the friction between LixSi alloy and SS
substrate, the linear relationship between 1-D critical cracking size and film thickness
gives a relation of with =2, close to our prediction 2.16. It has been known that
the adhesion strength between active materials and the substrate plays an important role
in cycling performance and that cracking could affect the bounding strength [118]. Local
buckling and delamination as a result of weak bonding between the active material film
and the substrate could also affect the crack patterns [92]. However, since few peeling-off
events were observed in this work, we assume that the a-Si layer has good adhesion with
the SS substrate during cycling.
From the discussions above, once an interconnected crack pattern is formed, stress in the
thin film during cycling is not large enough to generate more cracks. We have observed
experimentally that after stabilization of cracking patterns during the initial cycle, crack
pattern does not change much with further cycling. However, surface roughness increases
with cycling. Comparing Fig. 4.7 with Fig. 4.3 (c), we found that primary cracks do not
change much with more cycling because the tensile stress is not large enough to generate
new cracks. This observation suggests that pre-generated cracking in electrodes with
proper dimensions could prevent further cracking in materials. It has been reported that
properly patterned Sn alloy thin film [40] and Si thin film [39] would not crack further
with electrochemical cycling. This method, pre-generating cracks in active materials or
patterning the electrodes, can be applied to design more durable LIB electrodes which do
not crack with cycling.
32
Furthermore, it is likely that a critical thickness for crack generation exists based on
Griffith’s fracture criterion of materials [136]. In this theory, crack initiates if the force to
drive the crack was greater than the cracking resistant force. Cracking would occur if the
stored strain energy was larger than the surface energy required for the new surface after
cracking [136]. According to Griffith’s energy criterion, there is a critical thickness
bellow which crack would not form. This critical thickness can be calculated as [136]
√
(4.2)
where and are Young’s modulus and Poisson’s ratio, respectively. is the stress in
thin film, and the cracking resistance force. is directly related to fracture toughness
of materials by
, where for plane stress condition. Although
mechanical properties for amorphous Si and its lithiated phases are largely unknown, we
can estimate the order of magnitude of the critical thickness for cracking in amorphous
Si. Taking =1 MPa m1/2
and =0.2 for a-Si [137], and =2 GPa [21], the calculated
critical thickness is on the order of several hundred nm. The actual critical thickness
should be smaller because the fracture toughness of LixSi is smaller than that of a-Si due
to softening effect of lithiation [137]. Fig. 4.8 shows that interconnected cracks do not
form in the 100 nm thick Si thin films up to 10 cycles of lithiation/de-lithiation. The
critical thickness for crack initiation in a-Si thin film is, therefore, between 100 and
200 nm.
In addition to the scaling behavior between cracking area and film thickness shown in Fig.
4.5, the shape of crack patterns varies with film thickness . Fig. 4.9 shows the area-
perimeter scaling and the fractal dimension of the crack patterns with different film
thickness. In this work, the fractal dimension is defined as the power of area to
perimeter. For all the films, the cracked areas or islands show a power-law scaling
behavior (Fig. 4.9 (a), 4.9 (b), and 4.9 (c)). For films with thickness between 1000 nm
and 500 nm, a fractal dimension close to 2 represents simple shape or Euclidean shape,
which is a result of crack growth. When the film thickness decrease to 300 and 200 nm,
33
decreases to 1.74 and 1.57, respectively, representing complicated shapes with
concave edges. The complicated shape is formed because many cracks stop propagating
before reaching other crack branches.
4.6 Conclusions
We investigated crack patterns generated during electrochemical cycling of amorphous Si
thin film electrodes with thickness ranging from 200 to 1000 nm. A modified spring-
block model was used to simulate the crack patterns. Cracks generated in thick films are
straight with a few sharp direction changes and the area separated by cracks is large. For
thin films cracks show more wiggles and the average cracked area is small. After primary
cracks form, crack patterns do not change further with electrochemical cycling, while the
surface became rougher. The experimental and simulation results suggest two directions
of designing electrodes which do not crack. One method is patterned electrodes in which
the pattern size is smaller than the average cracked size for that specific film thickness.
The other method is to reduce the film thickness to less than the critical thickness of
cracking ( is between 100 and 200 nm for amorphous Si on stainless steel substrate).
34
Figure 4.1 An illustration of the 2-D spring-block model. The model consists an array of
hexagons, with each side of the hexagon connected to its partner by a number of elastic
springs. Here 2 springs at each side are shown.
35
(a)
(b)
Figure 4.2 (a) First cycle potential profile for a 500 nm amorphous Si thin film. (b)
Cycling performance of 500, 200, and 100 nm thick a-Si thin films. Solid symbols
represent discharging and open symbols represent charging.
36
(a)
(b)
37
(c)
(d)
Figure 4.3 (a) An SEM image of a 500 nm a-Si film before electrochemical tests and
cracking patterns formed on a-Si thin films of different thicknesses: (b) 1000 nm thick,
after 5 cycles. (c) 500 nm thick, after 5 cycles. (d) 200 nm thick, after 10 cycles.
38
(a) (b) (c)
Figure 4.4 Simulated crack patterns representing selected conditions. The crack to slip
ratio was fixed to be 0.5, and the number of springs per side varies. (a) =10,
representing 1000 nm thick film. (b) =5, representing 500 nm thick film. (c) =2,
representing 200 nm thick film.
Figure 4.5 A scaling relationship between the average cracked area and the film
thickness . The slop is found to be 2.16.
39
Figure 4.6 Schematic of a fractured piece of a-Si during de-lithiation. There is a tensile
stress in the thin film during de-lithiation, and a friction
at the interface of active
material and substrate. Formation of the pattern could be a result of natural cracking due
to cycling, or could be artificially produced to avoid further cracking of electrodes.
Figure 4.7 An SEM image showing surface morphology of 500 nm thick Si films after
10 electrochemical cycles.
40
Figure 4.8 An SEM image showing surface morphology of 100 nm thick Si films after
10 electrochemical cycles.
(a)
41
(b)
(c)
42
(d)
Figure 4.9 Area-perimeter scaling for islands divided by cracks. The power law fitting
gives fractal dimensions , which is defined as the power of area to perimeter. (a) Film
thickness is 1000 nm, after 5 cycles. =2.01. (b) Film thickness is 500 nm, after 5 cycles.
=1.96. (c) Film thickness is 200 nm, after 10 cycles. =1.57. (d) as a function of
film thickness.
43
Chapter 5 Liquid Metal Alloys as Self-Healing Negative Electrodes for Lithium Ion
Batteries 3
5.1 Summary
Improving the capacity and durability of electrode materials is one of the critical
challenges lithium-ion battery technology is facing presently. Several promising anode
materials, such as Si, Ge, and Sn, have theoretical capacities several times larger than that
of the commercially used graphite negative electrode. However, their applications are
limited because of the short cycle life due to fracture caused by diffusion-induced stresses
(DISs) and the large volume change during electrochemical cycling. In this chapter, we
present a strategy to achieve high capacity and improved durability of electrode materials
using low-melting point metallic alloys. With gallium as an example, we show that at a
temperature above the melting point of Ga, a reversible solid-liquid transition occurs
upon lithiation (lithium insertion) and de-lithiation (lithium extraction) of Ga. As a result,
cracks formed in the lithiated solid state can be “healed” once the electrode returns to
liquid Ga after delithiation. This work indicates that cracking as a failure mode can be
remedied using liquid metal electrodes.
5.2 Introduction
Lithium-ion batteries (LIBs) with high energy capacity and long cycle life are employed
to power numerous consumer electronics devices, portable tools, implantable medical
devices, and, more recently, hybrid electric vehicles (HEVs) and pure battery electric
vehicles (BEVs) [2, 3]. Many elements react with Li to form binary alloys LixM (where
M is, for example, Si [36], Ge [14], or Sn [18]). Their theoretical (Columbic) capacities
are 3 to 12 times higher than that of graphite electrodes, as they host 2 to 4.4 Li atoms per
3 Reproduced from Journal of The Electrochemical Society, 158 (8): A845-A849 (2011).
Copyright © The Electrochemical Society 2011.
44
M atom, in contrast to a single Li atom per 6 C atoms. These LixM alloys also show a
discharge potential close to that of the Li/Li+
reaction [3]. These materials have, therefore,
been considered as potential negative electrodes for LIBs. However, low cycle life due to
mechanical degradation [90, 117] and current inefficiencies associated with undesired
electrochemical reaction during cycling limits the application of these high capacity
electrode materials in LIBs.
Previous studies of the past 15 years that are focused on improving electrode durability
can be divided into three categories: (1) alloying the Li-active materials with inactive
elements, (2) building nano-structural electrodes, and (3) adding conducting and/or non-
conducting buffer components. Alloying Li-active with inactive materials improves
battery cycle life significantly, such as alloying Sn with Cu [138] , Co [139], or Ni [140].
However, the total gravimetric and volumetric energy densities are lowered because the
inactive elements contribute to extra weight and volume. Nano-structural electrodes, such
as thin-film Si [35], Si nano particles [30], Si nanowires [36] and TiO2 nanowires [141],
as well as porous transition metal oxides [142, 143], show improvements in cycle life
compared to their bulk-material counterparts. However, nanostructuring reduces
volumetric capacity of electrodes because of low packing density of nanowires,
nanoparticles, and porous materials. Furthermore, nanostructured electrodes may suffer
from increased irreversible capacity degradation due to excessive solid electrolyte
interface (SEI) formation[47], and other deleterious reactions with the electrolyte
(leading to reduced current efficiency relative to the desired lithiation reaction), because
of their large surface area to volume ratio. Last, conducting additives and chemical
binders, such as carbon black and polyvinylidene fluoride (PVDF), have been shown to
improve the cycle life at the cost of extra mass and volume occupied by the additives.
In this chapter, we demonstrate a strategy of achieving high capacity and durability using
low-melting point, lithium active, liquid metals (LMs) as LIB negative electrodes. This
idea is based on the premise that fracture and decrepitation in LMs during cycling can be
self-healed by liquid-solid-liquid transition. We examine the reversibility of lithiation of
the LM pure Ga at 40°C, as a negative electrode for a LIB. Ga hosts 2 Li atoms per Ga
45
atom upon full lithiation, delivers a theoretical gravimetric capacity of 769 mAh g-1
by
forming Li2Ga alloy [144], and shows a discharge potential close to the Li/Li+
reaction. It
has been shown that LiGa alloys [145], CuGa alloys [146], and Ga confined in carbon
matrix [147] deliver capacities of about 200 to 400 mAh g-1
upon extended cycling.
5.3 Experimental Section
5.3.1 Cell Assembly
Commercial pure gallium (Ga) metal (99.99%, Alfa Aesar) was applied onto 0.025 mm
thick 304-type stainless steel (SS) foils (Alfa Aesar) without any binder or conducting
additive. The thickness of Ga film on SS substrate was controlled to be about 1 µm, and
the mass of Ga was precisely measured by a microbalance (XS205, Mettler Toledo).
Samples were assembled into CR 2025-type coin cells (Hohsen) in an argon-filled glove-
box (MBraun) with oxygen and moisture contents less than 0.1 ppm. Li metal foils
(99.9%, Sigma Aldrich) were used as the counter electrode (CE). One piece of Celgard
3501 separator soaked in the electrolyte solution consisting of 1M LiPF6 dissolved in a
mixture of ethyl carbonate and dimethyl carbonate (EC/DMC, volumetric ratio 1:1)
(Novolyte) was used in making the coin cells.
5.3.2 Electrochemical Measurements
Cycling performance of coin cells was evaluated using a potentiostat (VersaSTAT 3,
PAR). The cells were galvanostaticlly cycled between 2.0 V and 0.005 V at various rates.
During cycling, coin cells were kept in an environmental chamber (Test Equity) with
precise temperature controlled at 40, 20, and 10°C, according to the experimental needs.
The temperature fluctuation is less than ±0.1°C. In this work charging refers to lithiation
and discharging refers to delithiation. Electrochemical Impedance Spectrometry (EIS)
was conducted using a potentiostat (2273, PAR) at 40°C and 10°C, respectively. Before
each EIS measurement, coin cells were cycled 5 times for stabilization, and then held at
0.890 V until the current was less than 10 nA. The amplitude of the ac signal applied to
the electrodes was 8 mV and the frequency was varied from 105 to 5×10
-3 Hz.
46
5.3.3 Materials Characterization
Before characterization, the cycled cells were disassembled and the WE was washed by
DMC (99%, Alfa Aesar). Ex-situ x-ray diffraction (XRD) was carried out using a D8
Discover (Bruker AXS) system with Cu Kα radiation (wavelength 1.54 nm). Samples
were maintained at 40°C during XRD tests. Scanning electron microscopy (SEM)
imaging was performed using a Hitachi S-4300 with an acceleration voltage of 3 kV. A
high sensitivity energy dispersive x-ray spectrometer (EDS, PGT) was used to conduct
chemical analysis.
5.4 Results and Discussion
The melting point of pure Ga is 29.8°C. Electrochemical cycling tests in this work were
held at 40°C to ensure the liquid state of pure Ga. Different from the Ga-Li equilibrium
phase diagram [148] and observations of Li in Ga at 415°C [144], three intermetallic
phases, Li2Ga7, LiGa, and Li2Ga, form during the electrochemical reaction of Ga with Li
at 40°C. The potential-capacity profile in Fig. 5.1 clearly shows four narrow single-phase
regions, as well as two-phase regions (plateaus). The theoretical Coulombic capacity in
going from Ga to Li2Ga corresponds to 769 mAh per gram of Ga. The electrode used to
generate the data of Fig. 5.1 yielded 700 mAh/g, about 91% of the theoretical value,
which indicates that the vast majority of the Ga within the electrode was utilized for
reaction with Li. The hysteresis in the potential profile of Fig. 5.1 is not well understood
at this time; we suspect that although 50 hours were employed for each of the low-
current-density charge and discharge experiments, irreversible phenomena still intrude on
the results.
The morphology changes of Ga at various stages of cycling were examined by ex-situ
SEM, as shown in Fig. 5.2. Before cycling, the applied Ga forms a uniform thin layer on
the stainless steel substrate (Fig. 5.2 (a)). After full lithiation, the alloy becomes solid and
surface roughness increases (Fig. 5.2 (b)). Through-thickness interconnected cracks form
in the alloy primarily during delithiation (Fig. 5.2 (c)). After cycling, most cracks
47
disappear because the alloy returns to pure Ga, which is a LM at 40°C (Fig. 2d). Thus,
cracks are self-healed by the solid-to-liquid transformation of the Ga electrode.
Based on and electrochemical results and ex-situ XRD results, and consistent with the
previous work of Saint et al. [145], the electrochemical reaction of liquid Ga with Li at
40°C can be summarized to good approximation as
Lithiation: →
→
→ (5.1)
Delithiation: →
→
→ (5.2)
To further understand the effect of a liquid electrode on the electrochemical performance,
the discharging voltage-capacity profiles of (a) liquid Ga (40°C) and (b) solid Ga (21°C)
at a C/2 rate are compared in Fig. 5.3. For Ga at 40°C, the GaLix compounds are solid at
this temperature. After the cell reaches the final plateau near 0.9 V, the electrode is a
mixture of solid Li2Ga7 and liquid Ga. Because Li diffusion in liquid Ga is much faster
than in a solid, Li diffusion in solid Li2Ga7 is rate limiting at this stage. After reaching the
liquid Ga single phase (starting at about 0.95 V), most of the electrode is liquid and Li
diffusion is especially fast. Thus, the cell potential increases to the upper potential limit
quickly. For the case of solid Ga at 21°C, after reaching the final potential plateau, the
electrode is a mixture of solid Li2Ga7 and solid Ga, where Li diffusion is relatively slow.
Because of the slow diffusion, the boundary between Ga single phase region and Li2Ga7-
Ga two-phase region is not clearly defined. Hence, the potential rises much more slowly
for the case of solid Ga.
The discharging potential-capacity profiles of Ga LM in the second cycle with various
rates are compared in Fig. 5.4 (a). Before each discharging, the cells were charged at
C/20 rate to ensure full lithiation of Ga. It is seen that as the discharging rate increases,
the potential of each two-phase region increases slightly, which is an indication of
polarization due to limited diffusivity of Li in lithiated Ga phases. The total capacity
decreases with increasing discharging rate. Ga reaches a capacity of 626 mAh g-1
at C/5
48
discharging rate, which is a standard rate to evaluate the performance of electrode
materials. Even at a fast rate of 2C, Ga still delivers a considerable discharge capacity of
560 mAh g-1
. The formation of LiGa delivers a capacity of 385 mAh g-1
and that of Li2Ga
delivers a capacity of 769 mAh g-1
, which is the theoretical maximum capacity of Ga.
The capacity versus cycle number for liquid Ga at 40°C is shown in Fig. 5.4 (b).
Efficiency was calculated from the ratio of delithiation to lithiation in each cycle. The
charging rate was C/20 and the discharging rate was C/5. A gradual decrease of capacity
with cycling is apparent. Commercial lithium salt based electrolytes show fast Li
diffusivity and moderate application temperature range compare to other types of
electrolytes, such as ionic liquids and solid electrolytes. However, there is a drawback of
SEI forming on top of electrodes when the WE is charged (lithiated) to below 0.7 V vs.
the Li/Li+
reaction. The SEI consumes electrolyte, lithium, and electrode material. This
SEI layer cannot be dissolved during the reversal electrochemistry process and
contributes to irreversible capacity loss. For most negative materials, SEI formation
completes in the first few cycles and facilitates Li transportation during subsequent
cycling. In this work, because the Ga electrode is in liquid state at the beginning of
charging and returns to liquid at the end of discharging at each cycle, the SEI may come
off the electrode surface and is no longer stable. Thus, fresh SEI forms during every cycle
and brings irreversible capacity loss. This is likely the continuous capacity drop with
cycling, as indicated in Fig. 5b. To commercially apply liquid metal with low discharging
potential, formation of SEI has to be avoided using other methods, such as using
electrolytes that do not form SEI.
Fig. 5.5 shows the EIS measurements of Ga/Li coin cells. The measurements were
conducted at 0.890 V, which is Ga single phase region (Fig. 5.1). Both plots are
composed of a depressed semi-circle at high frequency range, a short straight line with
approximately 45° at medium frequency range, and a steeper ling at high frequency
range. The depressed semi-circle is attributed to SEI film and charge-transfer process, the
45° straight line is attributed to the Warburg diffusion process, which is lithium diffusion
in active materials, and the steeper line is the onset of finite length diffusion. The
49
Warburg diffusion happens at a frequency range of 125-3 Hz for 40°C, and 10-0.3 Hz for
10°C, which indicates that the charge-transfer process at high temperature is much faster.
The diffusion coefficient can be calculated for the Warburg diffusion stage using [149]
[
(
)]
where (cm3 mol
-1) is the molar volume of liquid or solid Ga, is Faraday constant,
is the area of WE, is the linear dependence of Z’ or Z’’ on ( is the angular
frequency), is the composition dependence of potential, respectively. The value of
is approximately calculated from potential profile of slow cycling (C/50 rate).
The diffusion coefficient of Li in liquid Ga is 1.4×10-9
cm2
s-1
for 40°C and is 3.7×10-11
cm2
s-1
for solid Ga at 10°C. The two orders of magnitude difference in the diffusion
coefficients consistent with the discussion of the voltage-capacity profiles in Fig. 5.3.
5.5 Conclusions
In this chapter, we demonstrate the concept of using low-melting point metal/alloys as
lithium-ion battery electrodes. A conceptual picture consistent with all of the
experimental observations is given in Fig. 5.6 for self-healing liquid metal electrodes.
The liquid metal electrode undergoes crystallization upon lithiation and transforms to a
solid electrode. During delithiation the solid phases are transformed to the liquid state.
Cracking forms in the electrode mostly during delithiation and can be self-healed by the
solid-to-liquid transformation. Since many low melting point alloys exist and can
potentially store large quantities of Li, the liquid metal approach demonstrated by liquid
Ga may be generalized to many systems of technological significance.
50
Figure 5.1 Galvanostatic voltage-capacity profile of Ga at 40°C. The cycling rate was
C/50. The letters a, b, c, and d correspond to different states for the SEM images of Fig.
5.2.
51
(a)
(b)
52
(c)
(d)
Figure 5.2 Morphology changes of Ga with cycling. Figures are taken from different
states of cycling depicted in Fig. 5.1: (a) Ga before cycling, (b) after full lithiation, (c)
cracks formation in Ga-Li alloy during delithiation, and (d) cracks are self-healed by the
solid-liquid transformation.
53
Figure 5.3 Discharging voltage-capacity profiles of liquid Ga (40°C) and solid Ga (20°C)
at C/2 rate.
54
(a)
(b)
Figure 5.4 Electrochemical data for the liquid Ga electrode. (a) Rate dependence of
discharging voltage-capacity profiles of Ga at 40°C. The cell was charged to 0.005 V at
C/20 rate before each discharging. (b) Capacity versus cycle number for liquid Ga at
40°C. The charging rate was C/20, and the discharging rate was C/5.
55
Figure 5.5 Nyquist plot of EIS of liquid (40°C) and solid (10°C) Ga at 0.890 V vs. Li/Li+.
Inset shows the magnified impedance spectra at high frequency.
56
Figure 5.6 Schematic of morphology changes in liquid electrode during cycling. (a)
Liquid metal electrode on a solid substrate before electrochemical cycling. (b) Liquid
solidifies and expands during lithiation. (c) Cracking occurs in solid mainly during
delithiation. (d) Electrode returns to the liquid state during delithiation. Cracks are self-
healed by the solid-to-liquid phase transformation.
57
Chapter 6 Potentiostatic Intermittent Titration Technique (PITT) for Electrodes
Governed by Diffusion and Interfacial Reaction 4
6.1 Summary
The Potentiostatic Intermittent Titration Technique (PITT) is one of the widely used
methods for determining the diffusion coefficient in electrochemical materials, such as
lithium diffusion in lithium-ion battery electrodes. The conventional PITT analysis
neglects interfacial resistance and assumes the system is diffusion controlled. For real
electrode systems, however, surface reaction, as well as diffusion, may be rate limiting.
In this chapter, we analyze PITT measurements for material systems with finite surface
reaction rates. For small amplitude potential steps, we derive analytic solutions for the
measured transient current associated with PITT, taking into account the effects of finite
surface reaction rates. Using the analytic solutions, the diffusion coefficient, surface
reaction rate, and the exchange current density can be determined simultaneously. An
example of lithium diffusion in amorphous silicon thin-film electrodes is used to
demonstrate the enhanced PITT approach.
6.2 Introduction
The potentiostatic intermittent titration technique (PITT) is a powerful technique to study
the thermodynamic and transport properties of materials encountered in electrochemical
processes. Because voltage and current can be controlled and measured precisely, PITT
has become a commonly used electro-analytical method. Specifically, PITT has been
used to measure the diffusion coefficient, , of solutes in host materials, as well as to
obtain quasi-equilibrium voltage-capacity profiles of battery electrodes after it was first
developed by Wen et al. to study LiAl alloys [149, 150]. Recently, PITT has been widely
4 Reproduced from The Journal of Physical Chemistry C, 116 (1): 1472-1478 (2012).
Copyright © American Chemical Society 2012.
58
applied to characterize lithium diffusion in various lithium-ion battery (LIB) electrode
materials, especially graphite negative electrodes [151, 152] and transition metal oxide
positive electrodes [153-159].
The original PITT theory was developed based on a thin-film geometry with diffusion
across the thin electrode dimension [150]. Diffusion of only one species was allowed and
nucleation of new phases was not considered. Furthermore, the surface reaction rate was
assumed to be infinitely fast; i.e., surface reaction resistance was not considered. In
practice, it has been challenging to apply PITT to electrochemical systems because many
systems do not satisfy all of the assumptions. Thus, several researchers have modified
PITT to be applicable to various electrochemical systems. For instance, Markevich et al.
analyzed the PITT theory in a phase-transformation region which involves slow
nucleation, and pointed out that determined by PITT is less accurate than that by the
galvanostatic intermittent titration technique (GITT) [160]. Levi et al. studied the PITT of
lithium-graphite in the two-phase regions using a two parallel diffusion paths model [161]
and a moving boundary model [162]. In addition to phase transformation, it has been
realized that the resistance to surface reaction may affect the overall electrochemical
behavior. For example, Montella considered possible limitations by insertion reaction
kinetics, and developed analytic solutions for PITT [163]. Levi et al. developed
approximate analytic solutions for PITT by considering Ohmic drop using a generalized
dimensionless kinetic parameter ( ) [164], and applied this technique to
lithium diffusion in polymer electrode using a two-step refinement method [165].
Churikov et al. considered phase transformation and surface resistance for lithium
diffusion in multiple spheres, and calculated of lithium in LiFePO4 by numerical fitting
of parameters to experimental data [166]. More recently, Delacourt et al. applied PITT to
determine the lithium diffusion coefficient in LiFeSO4F by using an analytic solution of
diffusion in spheres with surface reaction resistance [159].
In this chapter, we consider the influence of resistance to surface reaction in analyzing
the diffusion of species within a host material during PITT for small potential-step
excitations, and we provide analytic solutions to the concentration distribution and
59
resulting current response. Using this simple analytic model of PITT, one can determine
the diffusion coefficient and surface reaction rate (yielding the exchange current density)
simultaneously. Using lithium diffusion in thin film amorphous silicon as an example, we
show that the diffusion coefficient can be underestimated without considering the finite
surface reaction rate. This enhanced PITT model is expected to be applicable to many
systems wherein diffusion and surface reaction resistance are both important phenomena.
6.3 Thermodynamics and Electrochemistry
We consider the electrochemical reaction at the electrolyte-electrode interface
eLi
host
0Li (6.1)
representing the lithiation and delithiation of alloy-type LIB electrodes. Using the Butler-
Volmer relation, we express the current density at the electrode surface driven by the
surface overpotential [167, 168]
[
]
where is the exchange current density, is the symmetry factor, is the Faraday’s
constant, is the gas constant, and is the temperature. The surface overpotential is
given by , were is the applied surface potential of the electrode and is the
equilibrium potential. Our primary objective is to measure the Li diffusion coefficient
and ensure accuracy by correcting for the intrusion of interfacial resistance on the
measurement. Thus, we consider a treatment wherein the potential is stepped from its
initial equilibrium value to reach an effective steady state (to be denoted by subscript )
at the new potential value. Since the overpotential in a PITT experiment of the type we
consider is small, Eq. (6.2) can be linearized about small giving rise to what is
commonly referred to as linear kinetics [167]:
60
For sufficiently long times, the current and overpotential tends to zero and → .
For the PITT analysis, we consider small potential steps over which the lithium
concentration within the host material does not deviate substantially from its initial value.
Although and are both concentration dependent, they can be approximated, using
Taylor expansion about the final (equilibrated, steady state) concentration , as
|
|
|
|
Discarding terms of order and higher, represented by
, we obtain
the following expression of the current-potential-concentration reaction:
[ |
|
]
[ ( |
|
)]
Again, discarding terms of and higher, and noting per the discussion
above, we obtain
|
|
A similar perturbation analysis can be employed to show that for small potential
excitations, Fick’s law prevails for the Li flux relation. The intercalate flux at the
electrode surface is thus given by
where is the chemical diffusion coefficient associated with the concentration . Using
Eq. (6.4) and (6.5), we can write the interfacial boundary condition as
61
where |
|
is the electrochemical Biot number, a dimensionless parameter that
is the ratio of diffusion resistance to that of the surface reaction [90, 131], similar to the
dimensionless parameters Λ [163, 164, 169], [170, 171], and [172] from literature.
For a PITT experiment such as what we investigate, is a fixed value. A large
represents a fast surface reaction compared to diffusion and vice versa. Eq. (6.6) is
mathematically equivalent to the “radiation boundary condition” in heat transfer
problems [173] and surface evaporation to a well stirred environment [174].
6.4 Analytic Solutions
To describe the diffusion of the guest within the host material consistent with the
previous discussion, we recognize that for small overpotential excitations and deviations
in , the diffusion equation can be linearized [175] . Thus, we employ Fick’s Second
Law
to describe the solid-state lithium diffusion through the thickness of a slab during the
PITT analysis.
Initially, lithium is in equilibrium within the electrode:
The electrode is connected to the current collector at one end ( ) and lithium cannot
transport through the electrode and current collector interface. Thus, we have a boundary
condition
62
Using the analogy between heat conduction [173] and diffusion [174], the analytic
solutions of concentration profile can be acquired. The solution may comprise error
functions or trigonometric series, for short or long times, respectively.
The analytic solution of Eq. (6.7), with initial condition (6.8a) and boundary condition
(6.6) and (6.8b), is [173]
∑
[ ( )]
(
)
where ( =1, 2, 3,…) are the positive roots of . This solution converges
quickly for long times, i.e.,
. The solution can also be expressed in terms of error
functions that converge rapidly for short time (
) [173]:
√ (
)
√ √
√
(
)
√ √
Dimensionless concentration profiles in the electrode for various values at short times
are plotted in Fig. 6.1. When the electrochemical Biot number is large, i.e. =100
in Fig. 6.1 (a), the surface reaction is fast compared to the diffusion process. The
concentration just inside the surface reaches quickly. The concentration profile is
similar to the case of infinitely fast surface reaction, as in the original PITT theory
developed by Wen et al [149, 150].
When the surface reaction rate is comparable with diffusion, i.e. =5 in Fig. 6.1 (b), the
concentration near the surface increases slowly to . The characteristics of the
concentration profile are between that which is obtained for constant concentration and
constant flux boundary conditions. When the surface reaction is rate-limiting, i.e. =0.05
in Fig. 6.1 (c), the concentration inside the electrode increase slowly (note the small
63
range of concentration in Fig. 6.1 (c)). In this case, the problem statement tends to that of
constant flux [90, 117, 149, 163]. This can be further demonstrated by examining
concentration profiles at longer time.
The electric current is related to the concentration gradient of solute at the electrode-
electrolyte interface, as described by Fick’s First Law. Neglecting higher-order terms, the
short time (
) transient current under potentiostatic operation corresponds to
(
) ( √
)
where we have employed the relation ) [149]. Here is the total
charge transferred during the applied potential step ∫
, is the surface area of the
electrode, and is the charge number of the electro-active species ( =1 for Li+).
Comparing Eq. (6.11) with the traditional expression for the electric current under PITT
operation (Eq. (15) in Reference [149]), we note that the electrochemical Biot number, as
well as the diffusion coefficient, enters in the equation for the electric current.
Furthermore, when the surface reaction is infinitely fast compared to diffusion, or when
approaches infinity, we have
→
→
(
) ( √
)
√
This is the same as the current response to constant surface concentration condition (Eq.
(15) in Reference [149]).
Using Eq. (6.11), we plot the dimensionless transient current response vs.
with
for various in Fig. 6.2. When is infinitely large, the transient current for short time is
a straight line with the slope equal to √
, consistent with the constant surface
64
concentration condition. As decreases, the range of the linear region and the slope of
the current vs.
both decrease. Since the diffusion coefficient is determined by
the slope of the linear region in the original PITT theory, the diffusion coefficient may
be underestimated using the linear fitting method when is finite or interfacial resistance
is large, which is consistent with previous publications [163, 176].
The concentration profile in the electrode with different at long times
is plotted
in Fig. 6.3. When the surface reaction rate is facile relative to the diffusive process
( =100 in Fig. 6.3 (a)), the concentration just inside the surface reaches the maximum
concentration quickly, and the concentration profile is close to constant concentration
condition. The concentration in the electrode increases quickly and the dimensionless
concentration reaches 0.9 when
is greater than 1.1. Similar trends in concentration
profiles can be found in Fig. 4 of Ref. [163], which illustrated the concentration evolution
under diffusion controlled processes [163]. When surface reaction is comparable to the
diffusion, i.e. =5 in Fig. 6.3 (b), the concentration in the electrode increases slowly. The
concentration just below the surface is smaller than unity at
=2, and the entire
dimensionless concentration does not reach 0.9 until
is greater than 1.4. When surface
reaction is the rate-limiting process ( =0.05 in Fig. 6.3 (c) and 6.3 (d)), the concentration
inside the electrode increases slowly. This is similar to the concentration profiles for
galvanostatic (constant flux) operations [90, 117, 149, 163]. Under this condition,
concentration in the electrode increases quasi-uniformly to reach the maximum value
(Fig. 6.3 (d)).
Substituting Eq. (6.9) into equation (6.5) and neglecting the higher-order terms, we find
that the transient current at large time (
) can be expressed as
(
)
Rearrangement of Eq. (6.13) yields
65
[ ] (
) [
(
)]
Fig. 6.4 shows the plot of [ ] (
) vs.
for various values. The slope of
the line is
when is infinite. With decreasing , the slope of the linear fit of the
curve decreases. The intercept of the line is 0 only when is infinity. With decreasing ,
the intercept of the line is negative. Thus, can be underestimated by using the slope or
intercept of [ ] vs. plot without considering the effect of surface reaction rate (cf.
equation (16) in Reference [149]), in agreement with previous publications [163, 176].
As → , →
, and we have
→
→
[
(
)]
Eq. (6.15) is the same as current response to constant concentration condition at long time
(Eq. (16) in Reference [149]).
According to Eq. (6.14), and can be determined simultaneously from the linear plot
of vs. by solving three equations:
[
]
6.5 Experimental
6.5.1 Sample Preparation
Amorphous Si thin films were deposited on Cu foil by means of E-beam evaporation.
The Si working electrode (WE) was assembled into CR2032 coin cell with pure lithium
66
metal (Alfa Aesar) as the counter electrode (CE). One piece of Celgard 3501 separator
soaked with electrolyte (1 M LiPF6 salt in 1:1 ratio of ethylene carbonate:dimethyl
carbonate) was used in the coin cell.
6.5.2 Electrochemical Characterization
Electrochemical tests were conducted using a Bio-Logic potentiostat (VMP3) at room
temperature. Before the PITT experiment, the coin cell was galvanostatically cycled four
times between 1.0 and 0.3 V in order to form a substantially stable SEI layer and remove
the influence of side reactions that are prevalent during the first couple cycles. The lower
voltage limit of 0.3 V was chosen to ensure shallow cycling and prevent cracking in the
Si thin films [177], which may affect diffusion behavior. Within each half cycle, the
capacity was measured to be less than 20% of the theoretical capacity of Si. The PITT
experiment was carried out during discharging from 0.395 V to 0.390 V. Voltage was
applied on the cell until the current fell below the equivalent of 1 mA g-1
(about C/3600).
The 1000 and 100 nm thick Si films were used for short time and long time evaluation of
PITT, respectively.
6.6 Results and Discussion
The diffusion coefficients calculated by different methods are compared in Table 6.1.
For testing the short time non-linear fitting method, PITT data were obtained during <
400 s (Fig. 6.6) using a 1,000 nm thick Si film. For testing the long time linear fitting
method, PITT data were collected during > 600 s (Fig. 6.7) using a 100 nm thick Si
film. The data points displayed are much fewer than the actual experimental data points
so that the data and the fit can be discerned. For short times, is calculated by a least-
square nonlinear fitting method (Curve Fitting Toolbox in Matlab) according to Eq. (6.11)
and linear fitting according to Eq. (15) in Reference [149]. For long times, is calculated
by solving Eq. (6.16) with parameters obtained from Fig. 6.7. As shown in Table 6.1 the
diffusion coefficient of lithium in amorphous silicon at 0.390 V varies from 1.0×10-13
to
1.4×10-13
cm2
s-1
. The electrochemical Biot number is calculated to range from 45 to 50,
67
which shows that both surface reaction and diffusion contribute to the system behavior.
The lithium diffusion coefficient in amorphous Si using the traditional PITT theory are
calculated to range from be 0.7×10-13
to 1.1×10-13
cm2
s-1
, close to values reported
previously [178-180]. The lithium diffusion coefficient calculated by either Eq. (6.10) or
Eq. (6.16) is larger than that calculated by the traditional short and long time linear fitting
methods. The results suggests that the diffusion coefficient may be underestimated using
the traditional methods when surface reaction rate is not infinitely fast or is finite.
Because the electrochemical Biot number is relatively large here, the system is biased to
diffusion control, and the diffusion coefficients obtained considering the surface reaction
rate are close to those using traditional methods. The diffusion coefficient calculated
using traditional methods may be much smaller if the surface reaction is slow or if, more
generally, is smaller, such as can be the case for graphite electrodes [90].
Furthermore, the exchange current density | can be calculated from the definition of
the electrochemical Biot number in Eq. (6.6). Note that the dependence of equilibrium
potential on concentration,
| , can be obtained separately by slow (quasi-equilibrium)
cycling. In this work, we applied C/300 cycling of Si vs. Li to obtain the equilibrium
potential profile. The exchange current density of silicon electrodes during lithiation at
0.390 V is calculated to range from 0.07 to 0.13 mA cm-2
. It is interesting to note that this
is nearly the same value as was obtained in the GITT experiment reported in Fig. 5 of
Reference [181] for a lithiated carbon electrode (approximately 0.1 mA cm-2
for
fractional occupancies of lithium ranging from 0.3 to 0.75) [181].
The surface reaction rate can be affected by the charge-transfer processes at the surface of
the LIB electrodes. For negative electrodes of LIBs, it can also be affected by the
presence of the solid electrolyte interphase (SEI). Properties of the SEI, including the
chemical composition, thickness, stability, and mechanical properties, vary with electrode
materials and the electrochemical environment. Surface modification, such as atomic
layer deposition (ALD) coating and surface fuctionalization, may change the surface
reaction rate. In general we expect the surface reaction resistance to affect the
68
electrochemical behavior of electrodes, as well as the transient current response to
potential steps.
6.7 Conclusions
We analyze the diffusion equation suitable for PITT when surface reaction resistance is
important and derived analytic solutions for the concentration and transient current
response. This treatment allows one to capture the additional influence of reaction
resistance, relative to the conventional PITT analysis, in a single dimensionless group:
the electrochemical Boit number , representing the ratio of diffusion resistance to that
of the surface reaction. We show that the diffusion coefficient can be underestimated
using the traditional linear ( vs. for short time) and exponential fitting ( vs. for
long time) methods without considering the influence of a finite surface reaction rate.
Using this new method, we show that one can determine the diffusion coefficient and
surface reaction rate simultaneously from a PITT measurement, as well as the exchange
current density. We implement the modified PITT to examine lithium diffusion in
amorphous silicon thin-film electrodes. The modified PITT is applicable to lithium-ion
battery electrodes, as well as other electrochemical systems wherein the measurement of
diffusion and kinetic parameters characterizing surface reaction resistance (e.g., the
exchange current density) are of interest.
6.8 Appendix
6.8.1 List of Symbols
electrochemical Biot number
molar concentration
diffusion coefficient of the solute
69
e electron
Faraday’s constant
current
current density
exchange current density
Li lithium ion
thickness of electrode
total charge transferred during a potential step
surface area of electrodes
time
equilibrium potential
surface potential
x thickness position
70
charge number of the electro-active species
symmetry factor
Surface overpotential
nth
positive roots of
dimensionless time
6.8.2 Derivation of The Electrochemical Biot Number Using Equivalent Circuit
The electrochemical Biot number can also be derived from a point of view of
equivalent circuit, which was used to estimate the interfacial kinetics occurring on ion-
insertion electrodes [163, 164]. Neglecting the limitations of mass transport in the
electrolyte, the resistance of an lithium-ion battery typically consists of three parts: the
charge transfer resistance , the resistance due to Ohmic drop , and the diffusion
resistance .
The interfacial charge-transfer resistance can be expressed as [163, 169]
where is Faraday’s constant, is the lithium ion insertion reaction rate, is the surface
area of the electrode, and is the surface equilibrium potential.
is particle derivative
of insertion reaction rate with respect to surface equilibrium potential .
The diffusion resistance can be expressed as [163, 169]
71
|
where is the thickness of the electrode, is the diffusion coefficient, and is the
concentration in the electrode. The insertion reaction rate is related to the Bulter-
Volmer equation (Eq. 6.2) by
[
]
where is the current density, is the exchange current density, is the symmetry factor,
is the gas constant, and is the temperature. The surface overpotential is given by
, were is the applied surface potential of the electrode. Assuming that the
overpotential is small, we can expand Es. (6.19) and obtain
|
Thus,
|
Using Eq. (6.18) and (6.21), the electrochemical Biot number , which is defined in Eq.
(6.6) in the main text, can be written as
|
|
where we have used
|
| . The electrochemical Biot number is, therefore, the
same as the dimensionless parameter
used by Montella [163] and
Vorotyntsev et al [164], if the resistance due to Ohmic drop is 0. As a result, if is 0,
72
the expressions of transient current Eqs. (6.11) and (6.13) are equivalent to Eqs. (39) and
(43) in Reference [163].
73
0.08
0.06
0.04
0.02
(a)
0.080.06
0.04
0.02
(b)
74
0.080.06
0.04
0.02
(c)
Fig. 6.1 Concentration profiles under PITT operation at short times, i.e.
, for
different electrochemical Biot numbers. (a) =100. (b) =5. (c) =0.05.
75
Fig. 6.2 Dimensionless transient current vs. time at short times with various
electrochemical Biot numbers.
76
(a)
(b)
77
(c)
(d)
Fig. 6.3 Concentration profiles under PITT operation at long times, i.e.
, for
different electrochemical Biot numbers. (a) =100. (b) =5. (c) =0.05.
78
Fig. 6.4 Dimensionless transient current vs. time at long times with various
electrochemical Biot numbers.
79
Fig. 6.5 Plot of transient current vs. at short time.
Fig. 6.6 Exponential dependence of current on time at long time.
80
Table 6.1 Diffusion coefficient of Li in silicon calculated by different methods.
Method (cm2
s-1
)
Short time (Eq. 6.10) 1.4×10-13
49.4
Short time linear fitting (Eq. 15 in Ref. [149]) 1.1×10-13
Long time (Eq. 6.17) 1.0×10-13
45.7
Long time (Eq. 16 in Ref. [149], slope) 7.7×10-14
Long time (Eq. 16 in Ref. [149], intercept) 7.7×10-14
81
Chapter 7 Potentiostatic Intermittent Titration Technique (PITT) for Electrodes
Governed by Diffusion and Interfacial Reaction
7.1 Summary
The potentiostatic intermittent titration technique (PITT) is an electroanalytical method
that has been widely used to study diffusion of solutes (such as lithium) in electrode
materials. Here, we extend the conventional PITT method to account for finite interfacial
reaction kinetics and derive analytic equations for electric current under PITT operations.
Using the modified PITT, the lithium diffusion coefficient in host materials and the
interfacial reaction kinetics can be determined simultaneously. We demonstrate this
modified PITT by an example of lithium diffusion in graphite (mesocarbon microbeads,
MCMB) and show the improvements of the modified PITT theory over the conventional
PITT for investigating the kinetics of electrodes comprising spherical particles.
7.2 Introduction
The potentiostatic intermittent titration technique (PITT), originally proposed by Huggins
et al. for studying Li diffusion in Li-Al alloy [149, 150], has been widely used in
studying diffusion and thermodynamics of lithium-ion batteries (LIBs), especially for
measuring the lithium diffusion coefficients in LIB electrodes. [157, 159, 161, 162, 166,
182-185] In developing the original theory, several assumptions were made for the
electrochemical system, including:
(1) Diffusion of only one species occurs in the system and the diffusion coefficient is a
constant within the applied potential range.
(2) Diffusion occurs across the thinnest dimension of a dense electrode with a slab
geometry.
(3) There is no interfacial reaction resistance at the electrode-electrolyte interface.
82
(4) There is no phase transformation related kinetics.
For solid-state electrochemical systems such as LIBs, experiments have to be designed
carefully to meet all the assumptions above. For example, dense thin-film electrodes need
to be used, allowing Li diffusion along the thickness direction (assumption 2 above). The
applied voltage range should be small, insuring diffusion in a single phase region with a
constant diffusion coefficient (assumptions 1 and 4 above).
In order to apply PITT to a large range of experimental conditions, researchers have
applied modifications to the original PITT theory. For example, Levi et al. modified
PITT to study the lithium-graphite system in two-phase regions using a parallel path
diffusion model [161] and a moving boundary model. [162] Churikov et al. proposed an
approach to describe the transport process during PITT operation considering surface
reaction and phase transformation, and studied Li diffusion in LiFePO4 by simulating
experimental data. [166] Montella discussed PITT with slow interfacial kinetics and
Ohmic drop on electrodes using an equivalent circuit approach. He introduced a
dimensionless parameter , which is the ratio of diffusion resistance to the resistance of
charge transfer and Ohmic drop, [163] and discussed the effects of on errors in
determining the diffusion coefficient. [176] Deiss discussed the voltage dependence of
the PITT measured diffusion coefficients and proposed that this dependence may be a
result of neglecting the interfacial kinetics. [186] Levi et al. developed approximate
analytic solutions for PITT by considering Ohmic drop using an equivalent circuit
approach and introduced a dimensionless kinetic parameter ( ). [164] They
applied their technique to lithium diffusion in polymer electrodes with a two-step
refinement method. [165] Recently, we proposed a modified PITT for electrodes
governed by diffusion and interfacial reaction kinetics, and applied this method to study
Li diffusion in amorphous Si thin film electrodes. [187]
Since most of the practically used electrodes are made of powders, the original PITT
theory for slab geometry may not be applicable to lithium diffusion along the radial
direction of the particles. Deiss noticed this problem and suggested that the diffusion
83
coefficients obtained for composite electrodes using the original PITT theory may be
incorrect. [186] More recently, Delacourt et al. applied PITT to determine the lithium
diffusion coefficient in LiFeSO4F particles by using an analytic solution of diffusion in
spheres. [159]
In this chapter, we develop a PITT model for lithium diffusion in spherical particles with
finite electrode-electrolyte interfacial reaction rates. With the analytic solutions for
transient current, the diffusion coefficient and interfacial reaction kinetics can be
simultaneously measured. With graphite (mesocarbon microbeads, MCMB) as an
example, we show that this modified PITT can be used to study the lithium diffusion in
LIB electrode materials consisting of spherical particles.
7.3 Theory
7.3.1 Governing Equations and Analytic Solutions
We consider a diffusion process in an electrode consisting of homogeneous spherical
particles of radius . Lithium diffusion in the lithium salt based liquid electrolyte is often
much faster compared to the diffusion in electrode materials [188], and we assume that
the diffusion process is identical in each single particle under electrochemical operation.
Assuming that the diffusion coefficient is a constant during the diffusion process and
there is no phase transformation kinetics involved, assumptions that are valid for small
potential changes in single phase regions, the diffusion equation for a sphere is given by
[174]
(
)
where is concentration, and is the radial position ( ). The initial and
boundary conditions corresponding to PITT operation, i.e., potentiostatic variation within
a small range, are
84
Here, represents the initial concentration in the particle, and is the steady-state
concentration after PITT operation (concentration just outside the particle). The boundary
condition (Eq. 2c) is discussed in detail in Ref [187]. The electrochemical Biot number,
| | , is a dimensionless parameter that represents the ratio of
interfacial reaction rate to the diffusion rate. [90, 131, 187] Here is the exchange
current density, is the equilibrium potential, is the gas constant, is the temperature,
and the subscript reflects values associated with the end of the potential step
experiment. The range of the electrochemical Biot number is . A large value
represents systems governed by diffusion, and small represents systems where
interfacial kinetics is slow. This boundary condition is mathematically equivalent to the
surface evaporation [174] and radiation boundary condition in heat transfer problems.
[173]
The solution for the diffusion equation (Eq. (7.1)) subject to the initial and boundary
conditions (Eq. (7.2)) is [173, 174]
∑
(
)
where is the positive root of . The concentration function
can also be obtained using Laplace and inverse Laplace transforms and can be expressed
in terms of error functions, which converge fast at short times ( ):
85
{(
√
√ )
[ (
)
] [
√ √
]
[ (
)
] [
√
√
]}
The dimensionless concentration profiles at short times ( ) with various
values are calculated according to Eq. (7.4) and plotted in Fig. 7.1. When the system is
diffusion controlled, such as =50 in Fig. 7.1 (a), the concentration just inside the surface
increases quickly to the final concentration , showing the characteristics of a system
governed by a constant surface concentration boundary condition. [117] When the system
is controlled by both diffusion and interfacial kinetics, the concentration profile exhibits
features between constant concentration and constant flux boundary conditions, as shown
in Fig. 7.1 (b). When the system is controlled by interfacial kinetics, such as =0.005 in
Fig. 7.1 (c), the concentration just inside the electrode increases slowly with time (notice
the small range of the concentration in Fig. 7.1 (c)).
The dimensionless concentration profiles at long times ( ) with various
values are plotted in Fig. 7.2. We used the first 50 terms of the infinite series in Eq. (7.3)
to calculate the concentration profiles. When interfacial reaction is facile comparing to
diffusion, such as =50 in Fig. 7.2 (a), the concentration just inside the particle is close to
1 at . The overall concentration increases quickly, and reaches 0.9996 at
. For system controlled by both diffusion and interfacial kinetics, such as
=5 in Fig. 7.2 (b), the concentration profiles show characteristics between a constant
flux and a constant concentration boundary condition. When the interfacial reaction is
slow compare to diffusion, such as =0.05 in Fig. 7.2 (c), the concentration in the
86
particle increases almost uniformly, showing the characteristics of constant surface flux
boundary condition. Diffusion profiles for the slab geometry have similar trends and can
be found in the literature. [90, 117, 163, 187]
7.3.1 Transient Current for PITT
The local current for each particle is related to the concentration gradient at the particle
surface by Fick’s First Law
where is the charge number of the ions, is Faraday’s constant, and is the surface
area of the electrode. For the electrode considered in this analysis, the current distribution
throughout the electrode is assumed uniform. Thus, the current for the electrode is related
to the local current of each particle by
where is the volume of the electrode (including active materials and pores), is
the average volume of a single particle, and is the volume fraction of active materials
(AM) in the electrode. Assuming the particles are perfect spheres with identical size, the
total current under PITT operation can be obtained by substituting the expression of
concentration (Eq. (7.2) or (7.3)) and Eq. (7.5) into Eq. (7.6) and using the relationship
.
7.3.1.1 Current at Short times ( )
The current under PITT at short times is
87
{
(
√ )
[
] ( √
)
[
] (
√
√
)}
Here is the total charge transferred during the potential step for the whole electrode.
When the interfacial resistance is negligible or interfacial reaction is infinitely fast, i.e.,
→ , the current becomes
→
(
√ )
For the special case , see Appendix B. The transient current for short times is
plotted in Fig. 7.3 using Eqs. (7.7) and (7.8). When the interfacial kinetics are facile, the
dimensionless current plot at short times is a straight line vs. √ with a slope of
√ . Note that the intercept of this line and the -axis is not 0, and the slope is also
different from the response current for slab electrodes. [149, 187] With increasing
interfacial reaction resistance, the linearity of this curve decreases. Thus, diffusion
coefficients are underestimated using the linear fitting method without considering the
effect of interfacial kinetics. The position and shape of this curve are determined by two
unknown parameters, and , and the diffusion coefficient and dimensionless
parameter can be obtained by fitting the experimental PITT data using non-linear
fitting methods.
88
7.3.1.2 Current at Long times ( )
Similar to Eq. (7.7), the current for PITT at long times is calculated according to Eqs.
(7.3), (7.5), and (7.6) as
(
)
Rearranging Eq. (7.9), we obtain
( ) (
) [
(
)]
For infinitely fast interfacial kinetics, i.e., → , the current is
→
→
(
)
(
)
Appendix B treats the special case . The current at long times is plotted in Fig. 7.4
using Eqs. (7.10) and (7.11). It is seen that with slowing interfacial kinetics, the slope of
the line decreases and the intercept with the y-axis is changing. As a result, the diffusion
coefficient can be underestimated if interfacial kinetics resistance is not incorporated.
For long times ( ), the diffusion coefficient and dimensionless parameter
can be determined by solving the following equations simultaneously:
89
7.4 Experimental
7.4.1 Cell Fabrication
We applied the modified PITT to analyze lithium insertion into graphite (conventional
MCMB), an important electrode material that is employed in high energy and high power
applications. The electrode consists of 92 wt.% of MCMB and 8 wt.% of binder and
conducting additives. The thickness of the electrode is 65 μm and the average diameter of
MCMB particles is 18 μm. A piece of sample with diameter of 10 mm was used as the
working electrode and was assembled into a 3-electrode cell (HS-3E, Hohsen). The
counter electrode and reference electrode are pure lithium metal. The electrolyte used
was a solution of 1 M LiPF6 dissolved in 1:1 volume ratio of ethylene carbonate (EC) /
dimethyl carbonate (DMC, Novolyte).
7.4.2 Electrochemical Characterization
A potentiostat (VMP3, Bio-Logic) was used to conduct the electrochemical
measurements. The equilibrium voltage-capacity profile was obtained by the
potentiostatic Coulombic titration technique. The voltage of the cell was stepped between
1.0 V and 0.005 V using 5 mV steps. At each step the potential was held until the current
reached 0.09 μA g-1
, corresponding to a C/4000 rate. PITT experiments were carried out
during charging of the half cell (delithiation of graphite) from 0.100 V to 0.105 V with a
cutoff current of 0.09 μA g-1
(C/4000).
7.5 Results and Discussion
The quasi-equilibrium voltage-capacity profile of Li-graphite obtained by potentiostatic
Coulombic titration is shown in Fig. 7.5, where we observe the typical electrochemical
behavior of graphitic carbon, including the clearly defined single phase and two phase
regions. [7] The PITT experiment was carried out in the LiC12 single phase region. The
transient current under PITT operation is plotted in Fig. 7.6 and Fig. 7.7. For short times,
and values were obtained by a least-square nonlinear fitting method (Curve Fitting
90
Toolbox in Matlab) according to Eq. (7.7). For long times, and values were obtained
by solving Eq. (7.12) with parameters obtained experimentally in Fig. 7.7. The Li
diffusion coefficients in LiC12 and the interfacial kinetics parameter are summarized in
Table 1. The diffusion coefficients of Li in LiC12 are in the range of the values reported
previously. [160, 171, 189, 190] We note that it has been shown that when the chemical
potential of Li is used as the driving force for diffusion, a substantially constant diffusion
results Li fractions ranging from 0 to 1 in (LiC6). [191]
From the definition of in Eq. (7.2c), the exchange current density can be calculated.
Here we obtained | from the quasi-equilibrium potential profile. The exchange
current density of LiC12 is calculated to be 0.75 to 0.78 mA cm-2
, several times larger
than the exchange current densities of graphitic carbon fibers [181] and amorphous Si
electrodes reported previously. [187] The modified PITT thus allows simultaneous
determination of diffusion coefficient and the exchange current density for Li in LiC12.
Although the Li diffusion coefficient in graphite MCMB determined by the modified and
the original PITT is similar because of the fast interfacial kinetics, it should be noted that
it is improper to use the original PITT theory (cf. Eqs. 15 and 16 in Ref. [149]) to
calculate the diffusion coefficient in powder electrodes, in which ( is the thickness
of the electrode) is taken as the time constant for diffusion instead of ( is the
radius of a single particle). The error may become large if the electrode thickness is much
larger than the particle size. Eqs (7.8) and (7.11) can be used to calculate the diffusion
coefficient in electrodes consisting of spherical particles if the interfacial kinetics is
negligible.
The diffusion coefficient can also be affected by interfacial reaction kinetics. The
electrochemical Biot number for MCMB electrodes obtained in this work ranges from
53.4 to 62.8, representing relatively fast interfacial kinetics, and is consistent with a
previous prediction. [90] The error in PITT determined diffusion coefficients without
considering the interfacial kinetics will become significant if the interfacial kinetics is
slow compared to diffusion, such as for particles with smaller diameters. [90]
91
7.6 Conclusions
We examined PITT for spherical particles with finite interfacial reaction kinetics. Using
the analytical solutions for the electric current, we show that one can obtain the diffusion
coefficient and interfacial kinetics simultaneously. As an example application of this
work, we investigate lithium diffusion in graphite (mesocarbon microbeads, MCMB),
and we show that the diffusion coefficient, interfacial kinetics, and exchange current
density can be determined simultaneously according to Eqs (7.7) and (7.12) for short
times ( ) and long times ( ), respectively. If the interfacial reactions
are facile, the diffusion coefficients can be determined by Eq. (7.8) and (7.11). This
modified PITT is expected to be generally applicable for obtaining interfacial charge
transfer reaction rates and diffusion coefficients for electrodes comprising substantially
spherical particles.
7.7 Appendix
7.7.1 List of Symbols
surface area of an electrode
electrochemical Biot number
molar concentration
initial concentration
equilibrated concentration after PITT
diffusion coefficient of the solute
92
Faraday’s constant
current for the electrode
local current at the surface of each particle
exchange current density
total charge transferred for the electrode during a potential step
total charge transferred for a single particle during a potential step
radial position
radii of particles
gas constant
time
temperature
equilibrium potential
volume of the electrode
93
volume of a particle
charge number of the electro-active species
symmetry factor
volume fraction of active materials in the electrode
nth
positive roots of
dimensionless time
7.7.2 Analytic Solutions of Concentration and Current when =1
At short times ( ), the analytic solution for concentration with =1 is
{(
) (
√ ) (
) (
√ ) √
[ (
√ )
]
√
[ (
√ )
]}
The current for short times becomes
{
√ √
√
[ (
√ )
]}
At long times ( ), the solution for concentration with is [90]
94
∑
[
]
[
]
[ (
)
]
The current is
[
(
)]
(
)
95
(a)
(b)
96
(c)
Fig. 7.1 Concentration profiles in an individual particle under PITT operation at short
times ( ) for different electrochemical Biot numbers. (a) =50. (b) =5. (c)
=0.05.
97
(a)
(b)
98
(c)
Fig. 7.2 Concentration profiles in an individual particle under PITT operation at long
times ( ) for different electrochemical Biot numbers. (a) =50. (b) =5. (c)
=0.05.
99
Fig. 7.3 Dimensionless transient current vs. time at short times ( ) with
various electrochemical Biot numbers.
Fig. 7.4 Dimensionless transient current vs. time at long times ( ) with various
electrochemical Biot numbers.
100
Fig. 7.5 Quasi-equilibrium potential-composition profile of Li-graphite (MCMB)
obtained by potentiostatic Coulombic titration.
101
Fig. 7.6 Plot of transient current vs. at short times.
Fig. 7.7 Exponential dependence of current on time at long times.
102
Table 7.1 Diffusion coefficient and interfacial kinetics of Li in MCMB (LiC12) obtained
from modified PITT.
Method (cm2
s-1
) (mA cm-2
)
Short times ( ), Eq. (7.7) 1.6×10-10
62.8 0.75
Long times ( ), Eq. (7.12) 1.8×10-10
53.4 0.78
103
Chapter 8 Conclusions and Future Work
8.1 Conclusions
Current commercial lithium-ion batteries (LIBs) do not meet the requirement of energy
storage for several fast growing products, especially hybrid and pure electric vehicles.
LIB electrodes with higher capacity, energy density, and cycle life are required. High
capacity negative LIB electrodes usually undergo large volume expansion and
contraction upon cycling. The associated large diffusion-induced stresses cause cracking
of the electrode materials, which further leads to loss of conduction and capacity fading.
In this dissertation, I focus on understanding the mechanical behavior of high-capacity
LIB negative electrodes and searching for strategies to avoid mechanical degradation.
Additionally, an electro-analytical technique (modified PITT) was proposed to measure
interfacial reaction kinetics and diffusion coefficients, which are essential for
understanding the effects of surface modification on LIB electrodes.
Tin (Sn) is a candidate material for negative electrodes of lithium-ion batteries (LIBs)
because of its high theoretical energy capacity. In Chapter 3, we study the behavior of Sn
thin-film electrodes, and show Sn-whisker growth on Sn thin-film electrodes after
lithiation and de-lithiation. The compressive stress generated by electrochemical
lithiation of the Sn-thin films, which is about 700 MPa, is likely the driving force for the
growth of the Sn whiskers. Similar to the phenomena of Li dendrite formation, Sn
whiskers may penetrate through the separator, and short-circuit the electrochemical cell.
As a result, attention should be paid to the issue of whisker growth in Sn-based electrodes
and other electrodes containing low melting point elements.
In Chapter 4, we study the fracture behavior and cracking patterns in amorphous silicon
(Si) thin film electrodes with thickness ranging from 100 to 1000 nm as a result of
electrochemical cycling. A modified spring-block model is shown to capture the essential
features of cracking patterns of electrode materials, including self-similarity. Cracks
generated in thick films are straight with a few sharp direction changes and the area
104
separated by cracks is large. For thin films cracks show more wiggles and the average
area divided by cracks is small. After primary cracks form, crack patterns do not change
further with electrochemical cycling, while the surface becomes rougher. As the
thickness of film decreases, the average size of islands separated by cracks decreases. A
critical thickness bellow which material would not crack is found for amorphous Si films.
The experimental and simulation results suggest two directions of designing electrodes
which do not crack: (1) patterning the electrodes in which the pattern size is smaller than
the average cracked size for that specific film thickness, and (2) reducing the film
thickness to less than the critical thickness of cracking, which is between 100 and 200 nm
for amorphous Si on stainless steel substrate.
In Chapter 5, we propose a new strategy to achieve high capacity and long durability of
LIB electrodes. We demonstrate the concept of using low-melting point metal/alloys as
self-healing LIB electrodes. The liquid metal gallium (Ga) electrode undergoes
crystallization upon lithiation and transforms to a solid electrode. During delithiation the
solid phases are transformed to the liquid state. Cracks formed in the electrode mostly
during delithiation can be self-healed by the solid-to-liquid transformation. This work
indicates that cracking as a failure mode can be remedied using liquid metal electrodes.
Since many low melting point alloys exist and can potentially store large quantities of Li,
the liquid metal approach demonstrated by liquid Ga may be generalized to many
systems of technological significance.
The Potentiostatic Intermittent Titration Technique (PITT) is one of the widely used
methods for determining the diffusion coefficient in electrochemical materials, such as
lithium diffusion in lithium-ion battery electrodes. The conventional PITT analysis
neglects interfacial resistance and assumes the system is diffusion controlled. For actual
electrode systems, however, surface reaction, as well as diffusion, may be rate limiting.
In Chapters 6 and 7, we derive modified PITT as an electro-analytical technique to
quantify the interfacial reaction kinetics as well as diffusion coefficients. For small
amplitude potential steps, we obtain analytic solutions for the measured transient current
associated with PITT, taking into account the effects of finite surface reaction rates. By
105
fitting experimental data with the analytic solutions, the diffusion coefficient, surface
reaction rate, and the exchange current density can be determined simultaneously. An
example of lithium diffusion in amorphous silicon thin-film electrodes is used to
demonstrate the modified PITT approach for slab geometry (Chapter 6), and an example
of lithium diffusion in graphite (mesocarbon microbeads, MCMB) is used to demonstrate
the modified PITT for spherical geometry (Chapter 7). The modified PITT is applicable
to LIB electrodes, as well as other electrochemical systems wherein the measurement of
diffusion and kinetic parameters (e.g., the exchange current density) are of interest.
8.2 Future Work
During the period of the author’s Ph.D. study, making better lithium-ion batteries
becomes a hot topic and draws attentions from researchers with a variety of backgrounds.
Each week there are about 50 to 200 new journal publications on the topic of lithium-ion
batteries. Though highly intensively researched, there is still no perfect method to
overcome some of the issues related to mechanical degradation of LIB electrodes. Thus,
there is plenty of room to improve lithium ion batteries in aspects of capacity, power,
cycling performance, power performance, safety, and cost.
In particular, future researchers are encouraged to (1) study cracking patterns or networks
in powder-shaped electrode materials, and extend the spring-block simulation model to 3-
D to predict cracking behavior in particles. (2) It is also interesting to investigate the
cracking behavior of low melting point electrode materials (such as Sn and Ga), and
analyze the differences from high melting point electrode materials (such as Si). (3) The
electroanalytical technique, modified PITT, can be used to quantify the effect of surface
modifications and coatings, and thus to help design ideal surface modification strategies
and to optimize the performance of LIB electrodes.
106
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battery solvents. Journal of Applied Electrochemistry, 30(3): 269-275. (2000)
189. H. Yang, H.J. Bang, and J. Prakash, Evaluation of electrochemical interface area
and lithium diffusion coefficient for a composite graphite anode. Journal of the
Electrochemical Society, 151(8): A1247-A1250. (2004)
190. M.D. Levi, E.A. Levi, and D. Aurbach, The Mechanism of Lithium Intercalation
in Graphite Film Electrodes in Aprotic Media. 2. Potentiostatic Intermittent
Titration and in situ XRD Studies of the Solid-State Ionic Diffusion. Journal of
Electroanalytical Chemistry, 421(1-2): 89-97. (1997)
191. D.R. Baker and M.W. Verbrugge, Intercalate Diffusion in Multiphase Electrode
Materials and Application to Lithiated Graphite. Journal of The Electrochemical
Society: in press. (2012)
123
Vita
Juchuan Li was born on January 23rd
, 1985 in Xiaxian County, Shanxi Province, P. R.
China.
EDUCATION
M.Eng., MSE, Tsinghua University, Beijing, 2007.
B.Eng., MSE, University of Science and Technology Beijing, Beijing, 2005
PROFESSIONAL AFFILIATIONS
Student Member, MRS, 2009-present
Student Member, ECS, 2010-present
Student Member, ASM International, 2011-present
AWARDS RECEIVED
Travel Grant for 220th
ECS meeting, ECS Battery Division, Boston, MA, 10/2011
Travel Grant for 219th
ECS meeting, ECS Battery Division, Montréal, Canada,
05/2011
Graduate Student Travel Scholarship, UK, 05/2011
First Place in Poster Category, UK CeNSE Annual Nanotechnology Contest, 12/2010
Graduate Student Travel Scholarship, UK, 04/2010
Excellent Final Thesis Award, USTB, 2005
PROFESSIONAL SERVICE
Session Co-Chair, “Microstructure, Mechanisms, and Modeling of Battery Materials”,
219th
ECS Meeting, Montréal, Canada, 05/2011
Secretary, MRS University of Kentucky Chapter, 2010-2011
124
PATENTS
1. Rutooj D. Deshpande, Juchuan Li, and Yang-Tse Cheng. “Using Liquid Metal as
Lithium-Ion Battery Electrodes”, provisional patent filed, 04/2011.
PUBLICATIONS
1. Qing Liu Wu, Juchuan Li, Rutooj D. Deshpande, Navaladian Subramanian,
Stephen E. Rankin, Fuqian Yang, and Yang-Tse Cheng. “Aligned TiO2 Nanotube
Arrays as Durable Lithium-Ion Battery Negative Electrodes”, submitted to J. Phys.
Chem. C. (Joint first-author with Q.L.W. and R.D.D.)
2. Juchuan Li, Xingcheng Xiao, Fuqian Yang, Mark W. Verbrugge, and Yang-Tse
Cheng. “Potentiostatic Intermittent Titration Technique (PITT) for Spherical
Particles with Finite Interfacial Kinetics”, submitted to Electrochimica Acta.
3. Rituraj Borgohain, Juchuan Li, John P. Selegue, and Yang-Tse Cheng. “Synthesis
and Electrochemical Study of Ruthenium Oxide-Modified Carbon Nano-Onions
for High-Performance Supercapacitor Electrodes”, submitted to J. Phys. Chem. C..
4. Juchuan Li, Xingcheng Xiao, Fuqian Yang, Mark W. Verbrugge, and Yang-Tse
Cheng. “Potentiostatic Intermittent Titration Technique for Electrodes Governed
by Diffusion and Interfacial Reaction”, J. Phys. Chem. C., 116 (1): 1472-1478
(2012).
5. Mark W. Verbrugge, Rutooj D. Deshpande, Juchuan Li, and Yang-Tse Cheng.
“The Search for High Cycle Life, High Capacity, Self Healing Negative
Electrodes for Lithium Ion Batteries and a Potential Solution Based on Lithiated
Gallium”, 2011 MRS Spring Meeting Proceedings, in press.
6. Rutooj D. Deshpande, Juchuan Li, Yang-Tse Cheng, and Mark W Verbrugge.
“Liquid Metal Alloys as Self-Healing Negative Electrodes for Lithium Ion
Batteries”, J. Electrochem. Soc., 158 (8): A845-A849 (2011).
7. Juchuan Li, Alan K. Dozier, Yunchao Li, Fuqian Yang, and Yang-Tse Cheng.
“Cracking Pattern Formation in Thin Film Lithium-Ion Battery Electrodes”, J.
Electrochem. Soc., 158 (6): A689-A694 (2011).
125
8. Juchuan Li, Fuqian Yang, Jia Ye, and Yang-Tse Cheng. “Whisker Formation on a
Thin Film Tin Lithium-Ion Battery Anode”, J. Power Sources, 196 (3): 1474-
1477 (2011).
9. Ju-Chuan Li, Jia-Lin Gu, and Chong-Lin Jia. “Effect of Heating Temperature on
Microstructure and Properties of Fe-Cr-Co Martensite Heat-Resistant Steel”, Heat
Treatment of Metals, 32 (9): 1-4 (2007).
CONFERENCE PRESENTATIONS
1. Oral presentation, “Aligned TiO2 Nanotubes as Long Durability Anodes for
Lithium-Ion Batteries”, MS&T’11, Columbus, OH, 2011.
2. Oral presentation, “Liquid Metal Alloys as Self-Healing Negative Electrodes for
Lithium Ion Batteries”, 220th
ECS Meeting, Boston, MA, 10/2011.
3. Oral presentation, “Cracking Pattern Formation in Thin Film Lithium-Ion Battery
Electrodes”, 219th
ECS Meeting, Montréal, Canada, 2011.
4. Poster, “Cracking and Whisker Formation in Thin Film Lithium-Ion Battery
Anodes”, 2011 KY Renewable Energy and Energy Efficiency Workshop,
Louisville, KY, 2011.
5. Poster, “Whisker Formation on a Thin Film Tin Lithium-Ion Battery Anode”,
Symposium on Energy Storage beyond Lithium Ion: Materials Perspectives, Oak
Ridge, TN, 2010.
6. Oral presentation, “In-situ Mass and Stress Measurement during Sn
Electrodeposition using an Electrochemical Double Quartz Crystal Microbalance
(E-DQCM) Technique”, 217th
ECS Meeting, Vancouver, Canada, 2010.
7. Poster, “Tin (Sn) Whiskers and Nanowires as Negative Electrodes for Li-Ion
Batteries”, 2009 MRS Fall Meeting. Boston, MA, 2009.
8. Poster, “Stress-Induced Sn Whiskers Growth”, 5th
Kentucky Innovation and
Entrepreneurship Conference, Louisville, KY, 2009.